mirror of
https://github.com/saitohirga/WSJT-X.git
synced 2024-11-26 22:28:41 -05:00
Removed many files not needed for map65, and fixed Makefile accordingly.
git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/map65@327 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
This commit is contained in:
parent
0e9621482f
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91
Announce.txt
91
Announce.txt
@ -1,91 +0,0 @@
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To: Users of WSJT
|
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From: Joe Taylor, K1JT
|
||||
Subject: WSJT 5.9.0
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Date: November 14, 2005
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|
||||
I am pleased to announce that WSJT 5.9.0 is available for free
|
||||
download from the WSJT Home Page,
|
||||
http://pulsar.princeton.edu/~joe/K1JT. It should appear soon
|
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on the European mirror site, http://www.dk5ya.de, as well.
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|
||||
I believe that all reported bugs found in beta-release version 5.8.6
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have been fixed. In addition, new enhancements have taken the program
|
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well beyond the capabilities of the baseline comparison versions,
|
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4.9.8 and 5.8.6.
|
||||
|
||||
The new WSJT 5.9.0 is faster and better than previous versions in a
|
||||
number of ways. A brief description of the enhancements since version
|
||||
5.8.6 can be found at
|
||||
http://pulsar.princeton.edu/~joe/K1JT/UpdateHistory.txt. There are
|
||||
many program changes, so be sure to read this information carefully
|
||||
before trying to use WSJT 5.9.0!
|
||||
|
||||
Of course there may be some new bugs, and perhaps I have overlooked an
|
||||
existing problem that you already know about. Please let me know if
|
||||
you find shortcomings in version 5.9.0, or if you have suggestions for
|
||||
further improvements.
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||||
|
||||
Sorry, I have not yet found time to implement EME Echo mode. When
|
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that is done, and when I have finished some further enhancements to
|
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the decoders, WSJT 6.0 will be born. With some luck, there may also
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be a new User's Guide at about that time.
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With best wishes,
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-- 73, Joe, K1JT
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Additional Information for Programmers
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-----------------------------------------------------------------------
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WSJT versions 5.8+ are the result of a complete re-write of the user
|
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interface, timing control, and audio I/O portions of WSJT 4.9.8. My
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principal motivation was to make the program multi-threaded, both for
|
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real-time operational convenience and for performance reasons.
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Another strong motivation was a desire to move the program away from
|
||||
its dependence on a proprietary compiler (Microsoft Visual Basic) and
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a single computer platform (Windows).
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||||
|
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The user interface of WSJT 5.8+ is written in Python -- an elegant,
|
||||
open, cross-platform language that has been a pleasure for me to
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learn. The remainder of the program is written mostly in Fortran,
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with some routines coded in C; much of that code has been carried over
|
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directly from WSJT 4.9.8.
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|
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I hope soon to release the source code for WSJT under the GNU General
|
||||
Public License (GPL). To this end, I have separated out the one piece
|
||||
of proprietary code formerly in the program -- the soft-decision Reed
|
||||
Solomon decoder licensed from CodeVector Technologies (CVT). A driver
|
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for this decoder, optimized for JT65, has been compiled into a
|
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stand-alone executable that is now distributed as part of the WSJT
|
||||
installation package, but not part of the program itself. With this
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approach I can honor all provisions of the CVT license, and at the
|
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same time release everything else as an open source program under the
|
||||
GPL.
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|
||||
WSJT 5.9.0 now includes an open source hard-decision Reed Solomon
|
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decoder based on code written by Phil Karn, KA9Q . WSJT uses this
|
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decoder automatically if the proprietary CVT decoder is unavailable.
|
||||
In such instances the "deep search" decodes retain their full
|
||||
sensitivity, but fully general decoding independent of the callsign
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database will be less sensitive by 2 or more dB, depending on signal
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fading characteristics. Separation of the program into two executable
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units is transparent to the user.
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WSJT 5.9.0 uses the following open source libraries, which are also
|
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available under the GPL:
|
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1. FFTW, by Matteo Frigo and Steven Johnson, for computing Fourier
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transforms
|
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|
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2. "Secret Rabbit Code" or "libsamplerate", by Erik de Castro, for
|
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accomplishing band-limited resampling of data
|
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|
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3. RS, by Phil Karn, KA9Q, for Reed Solomon encoding and
|
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hard-decision decoding.
|
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|
||||
I hope that the open release of WSJT source code will encourage others
|
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to read and understand the code, get involved in improving WSJT, and
|
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perhaps porting it to other platforms. Versions of the CVT
|
||||
soft-decision decoder for Linux or Macintosh will be easy to compile
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and distribute, if there is demand for them.
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|
@ -1,185 +0,0 @@
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<!DOCTYPE HTML PUBLIC "-//W3C//DTD HTML 4.0 Transitional//EN">
|
||||
<HTML>
|
||||
<HEAD>
|
||||
<META HTTP-EQUIV="CONTENT-TYPE" CONTENT="text/html; charset=utf-8">
|
||||
<TITLE></TITLE>
|
||||
<META NAME="GENERATOR" CONTENT="OpenOffice.org 2.0-pre (Linux)">
|
||||
<META NAME="CREATED" CONTENT="20060311;19474000">
|
||||
<META NAME="CHANGED" CONTENT="20060311;20035200">
|
||||
<STYLE>
|
||||
<!--
|
||||
PRE { font-family: "Thorndale AMT" }
|
||||
-->
|
||||
</STYLE>
|
||||
</HEAD>
|
||||
<BODY LANG="de-DE" DIR="LTR">
|
||||
<PRE>HowTo for Linux SuSE 10.0 ( DL3LST)
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||||
|
||||
Use Yast to install the following packages from the Linux Distribution DVD
|
||||
|
||||
Compiler
|
||||
cpp
|
||||
gcc
|
||||
gcc-c++
|
||||
liggcc
|
||||
|
||||
Tcl/tk
|
||||
tcl-devel
|
||||
tk-devel
|
||||
alsa-devel
|
||||
|
||||
Python
|
||||
python
|
||||
python-devel
|
||||
python-imaging
|
||||
python-numeric
|
||||
python-tk
|
||||
|
||||
--------------------------------------------------------------------------------------------------
|
||||
|
||||
// Fortran compiler
|
||||
Page: <A HREF="http://www.g95.org/"> http://www.g95.org/</A>
|
||||
Downloadpage: <A HREF="http://ftp.g95.org/"> http://ftp.g95.org/</A>
|
||||
Page: <A HREF="http://ftp.g95.org/g95-x86-linux.tgz"> http://ftp.g95.org/g95-x86-linux.tgz</A>
|
||||
|
||||
install: g95
|
||||
|
||||
follow instruction File: Install
|
||||
|
||||
How to install g95:
|
||||
|
||||
File Install:
|
||||
1) Unpack the downloaded tarball (e.g. g95-x86-linux.tgz) in a directory
|
||||
of your choice:
|
||||
|
||||
tar -zxvf g95-x86-linux.tgz
|
||||
|
||||
2) For your convenience, you can create another symbolic link from a
|
||||
directory in your $PATH (e.g. ~/bin) to the executable
|
||||
|
||||
ln -s $PWD/g95-install/bin/*g95* ~/bin/g95
|
||||
|
||||
|
||||
You should now be able to run g95 and create executables.
|
||||
To get a list of environment variables that control the library, run a
|
||||
compiled binary with the --help option, ie:
|
||||
|
||||
./a.out <20>help
|
||||
|
||||
From console try the g95 command .
|
||||
The system should answer
|
||||
g95: no input files
|
||||
|
||||
|
||||
I changed the SymLink to /usr/bin where i installed the g77 packages too
|
||||
ln -s $PWD/g95-install/bin/*g95* /usr/bin/g95
|
||||
|
||||
|
||||
|
||||
gcc-g77 compiler
|
||||
Page: <A HREF="http://sourceforge.net/project/showfiles.php?group_id=2435&package_id=82721&release_id=15880">http://sourceforge.net/project/showfiles.php?group_id=2435&package_id=82721&release_id=15880</A>
|
||||
Download: <A HREF="http://prdownloads.sourceforge.net/mingw/gcc-g77-3.4.2-20040916-1.tar.gz?download">http://prdownloads.sourceforge.net/mingw/gcc-g77-3.4.2-20040916-1.tar.gz?download</A>
|
||||
|
||||
From gcc-g77-3.4.2-20040916-1.tar.gz we need the /libexec folder for l2g
|
||||
copy from the archive the folder
|
||||
/libexec to /usr/libexec
|
||||
|
||||
------------------------------------------------------------------------------
|
||||
other packages
|
||||
------------------------------------------------------------------------------
|
||||
Install: PortaudioV1.19
|
||||
|
||||
Page: <A HREF="http://www.portaudio.com/usingsvn.html">http://www.portaudio.com/usingsvn.html</A>
|
||||
Download: <A HREF="http://www.portaudio.com/archives/pa_previous_snapshot_v19.tar.gz">http://www.portaudio.com/archives/pa_previous_snapshot_v19.tar.gz</A>
|
||||
./configure
|
||||
make all
|
||||
make install
|
||||
------------------------------------------------------------------------------
|
||||
FFT3
|
||||
Page : <A HREF="http://www.fftw.org/">http://www.fftw.org/ </A>
|
||||
Download : <A HREF="http://www.fftw.org/fftw-3.1.1.tar.g">http://www.fftw.org/fftw-3.1.1.tar.g</A>z
|
||||
./configure
|
||||
./make all
|
||||
./ make install
|
||||
|
||||
------------------------------------------------------------------------------
|
||||
libsamplerate
|
||||
libsamplerate-0.1.2.
|
||||
Download: <A HREF="http://www.mega-nerd.com/SRC/download.html">http://www.mega-nerd.com/SRC/download.html</A>
|
||||
./configure
|
||||
./make all
|
||||
./ make install
|
||||
------------------------------------------------------------------------------
|
||||
reed-solomon-4.0
|
||||
.Page: <A HREF="http://www.ka9q.net/code/fec/">http://www.ka9q.net/code/fec/</A>
|
||||
Download: <A HREF="http://www.ka9q.net/code/fec/reed-solomon-4.0.tar.gz">http://www.ka9q.net/code/fec/reed-solomon-4.0.tar.gz</A>
|
||||
/configure
|
||||
./make
|
||||
./ make install
|
||||
|
||||
|
||||
------------------------------------------------------------------------------
|
||||
F2PY ( Fortran to Python )
|
||||
Download: <A HREF="http://cens.ioc.ee/projects/f2py2e/2.x/F2PY-2-latest.tar.gz">http://cens.ioc.ee/projects/f2py2e/2.x/F2PY-2-latest.tar.gz</A>
|
||||
python setup.py install
|
||||
|
||||
|
||||
Scipy_Distutils
|
||||
Page: <A HREF="http://cens.ioc.ee/projects/f2py2e/2.x/">http://cens.ioc.ee/projects/f2py2e/2.x/</A>
|
||||
Download: <A HREF="http://cens.ioc.ee/projects/f2py2e/2.x/scipy_distutils-latest.tar.gz"> http://cens.ioc.ee/projects/f2py2e/2.x/scipy_distutils-latest.tar.gz</A>
|
||||
python setup.py install
|
||||
|
||||
|
||||
WSJT source code
|
||||
K1JT Page: <A HREF="http://pulsar.princeton.edu/~joe/K1JT/">http://pulsar.princeton.edu/~joe/K1JT/</A>
|
||||
Download page: <A HREF="http://developer.berlios.de/projects/wsjt/">http://developer.berlios.de/projects/wsjt/</A>
|
||||
|
||||
|
||||
./configure
|
||||
make
|
||||
python wsjt.py
|
||||
|
||||
that<EFBFBD>s all - have fun
|
||||
|
||||
------------------------------------------------------------------------------
|
||||
If you need the packages for other Linux distributions see linkpages below
|
||||
------------------------------------------------------------------------------
|
||||
|
||||
Python:
|
||||
Page. <A HREF="http://www.python.org/download/releases/2.4.3">http://www.python.org/download/releases/2.4.3</A>
|
||||
Download: <A HREF="http://www.python.org/ftp/python/2.4.3/Python-2.4.3.tgz">http://www.python.org/ftp/python/2.4.3/Python-2.4.3.tgz</A>
|
||||
/configure
|
||||
./make
|
||||
./ make install
|
||||
than run
|
||||
python setup.py install
|
||||
|
||||
|
||||
Numeric
|
||||
Page: <A HREF="http://numeric.scipy.org/"> http://numeric.scipy.org</A>/
|
||||
Download: <A HREF="http://prdownloads.sourceforge.net/numpy/Numeric-24.2.tar.gz?download">http://prdownloads.sourceforge.net/numpy/Numeric-24.2.tar.gz?download</A>
|
||||
install
|
||||
|
||||
Iimaging (be sure Tcl/Ck Lib was installed before)
|
||||
Page: <A HREF="http://www.pythonware.com/products/pil/">http://www.pythonware.com/products/pil/</A>
|
||||
Download: <A HREF="http://effbot.org/downloads/Imaging-1.1.5.tar.gz">http://effbot.org/downloads/Imaging-1.1.5.tar.gz</A>
|
||||
python setup.py install
|
||||
|
||||
------------------------------------------------------------------------------
|
||||
other sites
|
||||
------------------------------------------------------------------------------
|
||||
for gcc compiler try
|
||||
<A HREF="http://gcc.gnu.org/mirrors.html">http://gcc.gnu.org/mirrors.html</A>
|
||||
|
||||
Example German server
|
||||
<A HREF="ftp://ftp.fu-berlin.de/unix/languages/gcc/releases/gcc-4.1.0/">ftp://ftp.fu-berlin.de/unix/languages/gcc/releases/gcc-4.1.0/</A>
|
||||
<A HREF="ftp://ftp.gwdg.de/pub/misc/gcc/releases/gcc-4.1.1/">ftp://ftp.gwdg.de/pub/misc/gcc/releases/gcc-4.1.1/</A>
|
||||
|
||||
the full program ( !!! filesize is 21 MB )
|
||||
<A HREF="ftp://ftp.fu-berlin.de/unix/languages/gcc/releases/gcc-4.1.0/gcc-core-4.1.0.tar.gz">ftp://ftp.fu-berlin.de/unix/languages/gcc/releases/gcc-4.1.0/gcc-core-4.1.0.tar.gz</A>
|
||||
./configure
|
||||
make
|
||||
make install
|
||||
</PRE>
|
||||
</BODY>
|
||||
</HTML>
|
46
JT65code.f
46
JT65code.f
@ -1,46 +0,0 @@
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program JT65karn
|
||||
|
||||
C Provides examples of message packing, bit and symbol ordering,
|
||||
C Reed Solomon encoding, and other necessary details of the JT65
|
||||
C protocol.
|
||||
|
||||
character*22 msg0,msg,decoded,cok*3
|
||||
integer dgen(12),sent(63),recd(12),era(51)
|
||||
|
||||
nargs=iargc()
|
||||
if(nargs.ne.1) then
|
||||
print*,'Usage: JT65code "message"'
|
||||
go to 999
|
||||
endif
|
||||
|
||||
call getarg(1,msg0) !Get message from command line
|
||||
msg=msg0
|
||||
|
||||
call chkmsg(msg,cok,nspecial,flip) !See if it includes "OOO" report
|
||||
if(nspecial.gt.0) then !or is a shorthand message
|
||||
write(*,1010)
|
||||
1010 format('Shorthand message.')
|
||||
go to 999
|
||||
endif
|
||||
|
||||
call packmsg(msg,dgen) !Pack message into 72 bits
|
||||
write(*,1020) msg0
|
||||
1020 format('Message: ',a22) !Echo input message
|
||||
if(iand(dgen(10),8).ne.0) write(*,1030) !Is the plain text bit set?
|
||||
1030 format('Plain text.')
|
||||
write(*,1040) dgen
|
||||
1040 format('Packed message, 6-bit symbols: ',12i3) !Display packed symbols
|
||||
|
||||
call rs_encode(dgen,sent) !RS encode
|
||||
call interleave63(sent,1) !Interleave channel symbols
|
||||
call graycode(sent,63,1) !Apply Gray code
|
||||
write(*,1050) sent
|
||||
1050 format('Channel symbols, including FEC:'/(i5,20i3))
|
||||
|
||||
call graycode(sent,63,-1)
|
||||
call interleave63(sent,-1)
|
||||
call rs_decode(sent,era,0,recd,nerr)
|
||||
call unpackmsg(recd,decoded) !Unpack the user message
|
||||
write(*,1060) decoded,cok
|
||||
1060 format('Decoded message: ',a22,2x,a3)
|
||||
999 end
|
@ -1,20 +0,0 @@
|
||||
include 'JT65code.f'
|
||||
include 'nchar.f'
|
||||
include 'grid2deg.f'
|
||||
include 'packmsg.f'
|
||||
include 'packtext.f'
|
||||
include 'packcall.f'
|
||||
include 'packgrid.f'
|
||||
include 'unpackmsg.f'
|
||||
include 'unpacktext.f'
|
||||
include 'unpackcall.f'
|
||||
include 'unpackgrid.f'
|
||||
include 'deg2grid.f'
|
||||
include 'chkmsg.f'
|
||||
include 'getpfx1.f'
|
||||
include 'getpfx2.f'
|
||||
include 'k2grid.f'
|
||||
include 'grid2k.f'
|
||||
include 'interleave63.f'
|
||||
include 'graycode.f'
|
||||
include 'set.f'
|
126
Makefile.in.joe
126
Makefile.in.joe
@ -1,126 +0,0 @@
|
||||
CC ?= @CC@
|
||||
FFLAGS = @FFLAGS@
|
||||
LDFLAGS = @LDFLAGS@
|
||||
CPPFLAGS = @CPPFLAGS@
|
||||
CFLAGS = @CFLAGS@
|
||||
CFLAGS += -DBIGSYM
|
||||
|
||||
# WSJT specific Fortran flags
|
||||
#FFLAGS += -Wall -fbounds-check -cpp -fno-second-underscore
|
||||
FFLAGS = -O2 -cpp -w -fno-second-underscore
|
||||
|
||||
OS=@OS@
|
||||
G95=@G95@
|
||||
COMPILER=@G95_LIB_PATH@
|
||||
FC=@G95@
|
||||
|
||||
LDFLAGS += -L${COMPILER}
|
||||
LDFLAGS += -lg2c
|
||||
|
||||
PYTHON ?= @PYTHON@
|
||||
RM ?= @RM@
|
||||
F2PY = @F2PY@
|
||||
F2PY_PY = "f2py.py"
|
||||
|
||||
%.o : %.f90
|
||||
$(FC) -c $(FFLAGS) $< -o $@
|
||||
|
||||
OBJS1 = JT65code.o nchar.o grid2deg.o packmsg.o packtext.o \
|
||||
packcall.o packgrid.o unpackmsg.o unpacktext.o unpackcall.o \
|
||||
unpackgrid.o deg2grid.o packdxcc.o chkmsg.o getpfx1.o \
|
||||
getpfx2.o k2grid.o grid2k.o interleave63.o graycode.o set.o \
|
||||
igray.o init_rs.o encode_rs.o decode_rs.o \
|
||||
wrapkarn.o
|
||||
|
||||
F2PYONLY = ftn_init ftn_quit audio_init spec getfile azdist0 astro0
|
||||
|
||||
SRCS2F90 = a2d.f90 abc441.f90 astro0.f90 audio_init.f90 azdist0.f90 \
|
||||
blanker.f90 decode1.f90 decode2.f90 decode3.f90 ftn_init.f90 \
|
||||
ftn_quit.f90 get_fname.f90 getfile.f90 horizspec.f90 hscroll.f90 \
|
||||
i1tor4.f90 pix2d.f90 pix2d65.f90 rfile.f90 savedata.f90 spec.f90 \
|
||||
wsjtgen.f90 runqqq.f90 fivehz.f90
|
||||
|
||||
OBJS2F90 = a2d.o abc441.o astro0.o audio_init.o azdist0.o \
|
||||
blanker.o decode1.o decode2.o decode3.o ftn_init.o \
|
||||
ftn_quit.o get_fname.o getfile.o horizspec.o hscroll.o \
|
||||
i1tor4.o pix2d.o pix2d65.o rfile.o savedata.o spec.o \
|
||||
wsjtgen.o runqqq.o fivehz.o
|
||||
|
||||
SRCS2F77 = wsjt1.f astro.f astropak.f \
|
||||
avesp2.f bzap.f spec441.f spec2d.f mtdecode.f stdecode.f \
|
||||
indexx.f s2shape.f flat2.f gen65.f chkmsg.f gen6m.f gentone.f \
|
||||
syncf0.f syncf1.f synct.f decode6m.f avemsg6m.f \
|
||||
set.f flatten.f db.f pctile.f sort.f ssort.f ps.f smooth.f \
|
||||
ping.f longx.f peakup.f sync.f detect.f avemsg65.f decode65.f \
|
||||
demod64a.f encode65.f extract.f flat1.f four2.f rfile2.f \
|
||||
gencw.f getpfx1.f getpfx2.f getsnr.f graycode.f grid2k.f \
|
||||
interleave63.f k2grid.f limit.f lpf1.f deep65.f morse.f \
|
||||
nchar.f packcall.f packgrid.f packmsg.f packtext.f setup65.f \
|
||||
short65.f slope.f spec2d65.f sync65.f unpackcall.f \
|
||||
unpackgrid.f unpackmsg.f unpacktext.f xcor.f xfft.f wsjt65.f
|
||||
|
||||
OBJS2F77 = wsjt1.o astro.o astropak.o \
|
||||
avesp2.o bzap.o spec441.o spec2d.o mtdecode.o stdecode.o \
|
||||
indexx.o s2shape.o flat2.o gen65.o chkmsg.o gen6m.o gentone.o \
|
||||
syncf0.o syncf1.o synct.o decode6m.o avemsg6m.o \
|
||||
set.o flatten.o db.o pctile.o sort.o ssort.o ps.o smooth.o \
|
||||
ping.o longx.o peakup.o sync.o detect.o avemsg65.o decode65.o \
|
||||
demod64a.o encode65.o extract.o flat1.o four2.o rfile2.o \
|
||||
gencw.o getpfx1.o getpfx2.o getsnr.o graycode.o grid2k.o \
|
||||
interleave63.o k2grid.o limit.o lpf1.o deep65.o morse.o \
|
||||
nchar.o packcall.o packgrid.o packmsg.o packtext.o setup65.o \
|
||||
short65.o slope.o spec2d65.o sync65.o unpackcall.o \
|
||||
unpackgrid.o unpackmsg.o unpacktext.o xcor.o xfft.o wsjt65.o
|
||||
|
||||
#OBJS2F90 = a2d.o abc441.o astro0.o audio_init.o azdist0.o \
|
||||
# blanker.o decode1.o decode2.o decode3.o ftn_init.o \
|
||||
# ftn_quit.o get_fname.o getfile.o horizspec.o hscroll.o \
|
||||
# i1tor4.o pix2d.o pix2d65.o rfile.o savedata.o spec.o \
|
||||
# wsjtgen.o runqqq.o fivehz.o
|
||||
|
||||
#
|
||||
# ok, so far for now
|
||||
# Windows @AUDIO@ will be jtaudio.c since it uses portaudio
|
||||
# for *nix @AUDIO@ will also be jtaudio.c and start_threads.c
|
||||
# for portaudio
|
||||
# for *nix @AUDIO@ will be start_threads.c for alsa
|
||||
# for *nix @AUDIO@ will be ?? for oss
|
||||
#
|
||||
# ptt_unix.c vs. ptt.c I'll sort out later.
|
||||
# ditto for cutil.c (only used on *nix)
|
||||
# --db
|
||||
# jtaudio.c/start_threads.c mess will have to be sorted out later
|
||||
# to minimise #ifdef's
|
||||
# --db
|
||||
#
|
||||
OBJS2C = init_rs.o encode_rs.o decode_rs.o
|
||||
SRCS3C = ptt_unix.c igray.c wrapkarn.c cutil.c
|
||||
SRCS3C += @AUDIO@
|
||||
|
||||
all: JT65code wsjt6
|
||||
|
||||
JT65code: $(OBJS1)
|
||||
$(FC) -o JT65code $(OBJS1)
|
||||
|
||||
wsjt6: Audio.so #wsjt.spec
|
||||
# ${PYTHON} c:\python23\installer\Build.py wsjt.spec
|
||||
# ${RM} wsjt6
|
||||
|
||||
Audio.so: $(OBJS2C) $(OBJS2F77) $(SRCS2F90) ${SRCS3C}
|
||||
${PYTHON} ${F2PY_PY} -c --quiet --opt="-O -cpp -D${CFLAGS} \
|
||||
-fno-second-underscore" $(OBJS2C) $(OBJS2F77) -m Audio \
|
||||
--f77exec=${G95} --f90exec=${G95} ${CPPFLAGS} ${LDFLAGS} \
|
||||
only: $(F2PYONLY) : \
|
||||
$(SRCS2F90) \
|
||||
${SRCS3C}
|
||||
|
||||
wsjt.spec: wsjt.py astro.py g.py options.py palettes.py smeter.py specjt.py
|
||||
# ${PYTHON} c:\python23\installer\makespec.py --icon wsjt.ico \
|
||||
# --tk --onefile wsjt.py
|
||||
|
||||
four2.o: four2.f
|
||||
$(FC) -c -O2 four2.f
|
||||
|
||||
.PHONY : clean
|
||||
clean:
|
||||
${RM} -f *.o *.so JT65code wsjt6
|
2662
UpdateHistory.txt
2662
UpdateHistory.txt
File diff suppressed because it is too large
Load Diff
24
WSJT592.iss
24
WSJT592.iss
@ -1,24 +0,0 @@
|
||||
[Setup]
|
||||
AppName=WSJT
|
||||
AppVerName=WSJT Version 5.9.2 r77
|
||||
AppCopyright=Copyright (C) 2001-2005 by Joe Taylor, K1JT
|
||||
DefaultDirName={pf}\WSJT6
|
||||
DefaultGroupName=WSJT6
|
||||
|
||||
[Files]
|
||||
Source: "c:\k1jt\svn\wsjt\release-5.9.2\WSJT6.EXE"; DestDir: "{app}"
|
||||
Source: "c:\k1jt\svn\wsjt\release-5.9.2\README_592.TXT"; DestDir: "{app}"
|
||||
Source: "c:\k1jt\svn\wsjt\release-5.9.2\CALL3.TXT"; DestDir: "{app}"; Flags: onlyifdoesntexist
|
||||
Source: "c:\k1jt\svn\wsjt\release-5.9.2\wsjt.ico"; DestDir: "{app}"; Flags: onlyifdoesntexist
|
||||
Source: "c:\k1jt\svn\wsjt\release-5.9.2\TSKY.DAT"; DestDir: "{app}"; Flags: onlyifdoesntexist
|
||||
Source: "c:\k1jt\svn\wsjt\release-5.9.2\libsamplerate.dll"; DestDir: "{app}"; Flags: onlyifdoesntexist
|
||||
Source: "c:\k1jt\svn\wsjt\release-5.9.2\kvasd.exe"; DestDir: "{app}";
|
||||
Source: "c:\k1jt\svn\wsjt\release-5.9.2\wsjtrc.win"; DestDir: "{app}";
|
||||
Source: "c:\k1jt\svn\wsjt\release-5.9.2\Tutorial_592.txt"; DestDir: "{app}";
|
||||
Source: "c:\k1jt\python\wsjt\rxwav\samples\W8WN_010809_110400.WAV"; DestDir: "{app}\RxWav\Samples\"; Flags: onlyifdoesntexist
|
||||
|
||||
[Icons]
|
||||
Name: "{group}\WSJT6"; Filename: "{app}\WSJT6.EXE"; WorkingDir: {app}
|
||||
Name: "{userdesktop}\WSJT6"; Filename: "{app}\WSJT6.EXE"; WorkingDir: {app}
|
||||
|
||||
|
@ -1,283 +0,0 @@
|
||||
WSJT DEVELOPMENT OVERVIEW
|
||||
-------------------------
|
||||
|
||||
1 Introduction
|
||||
----------------------------------------------------------------------
|
||||
WSJT is a computer program designed to facilitate Amateur Radio
|
||||
communication under extreme weak-signal conditions. Three very
|
||||
different coding and modulation methods are provided: one for
|
||||
communication by "meteor scatter" techniques on the VHF bands; one for
|
||||
meteor and ionospheric scatter, primarily on the 6 meter band; and one
|
||||
for the very challenging EME (Earth-Moon-Earth) path.
|
||||
|
||||
|
||||
2 Program Overview
|
||||
----------------------------------------------------------------------
|
||||
WSJT's user interface is written in Python. The major Python
|
||||
source-code files include:
|
||||
|
||||
1. wsjt.py Defines the main-screen GUI for user interactions;
|
||||
acts as "traffic cop" for orchestrating all
|
||||
event-driven and time-shared activities.
|
||||
|
||||
2. specjt.py Provides real-time display of received signals as
|
||||
two-dimensional "waterfall" spectra.
|
||||
|
||||
3. options.py Provides entry fields for user-defined parameters.
|
||||
|
||||
4. astro.py Displays astronomical data for sun, moon, sky
|
||||
temperature, etc.
|
||||
|
||||
Smaller Python files serve various utility purposes.
|
||||
|
||||
Both wsjt.py and specjt.py make calls to external procedures compiled
|
||||
from Fortran and C. A variety of global data is shared among modules
|
||||
through common blocks defined in Fortran. The Python code runs in a
|
||||
single thread, although timers make the functions of the several main
|
||||
modules appear concurrent. Fortran routines create additional threads
|
||||
to be used for soundcard I/O and the decoding of received messages.
|
||||
|
||||
As a small part of its overall task, the decoder for JT65 invokes an
|
||||
external program named KVASD.EXE or KVASD, located in the main
|
||||
WSJT directory. If this program is present it uses information on
|
||||
received 64-FSK symbols and attempts to decipher it according to a
|
||||
Reed Solomon (63,12) code, using the algebraic soft-decision algorithm
|
||||
of Koetter and Vardy. If KVASD is not present, WSJT uses its own
|
||||
internal hard-decision Reed Solomon decoder instead. Interprocess
|
||||
communication between WSJT and KVASD takes place through a shared disk
|
||||
file. KVASD is not an integral part of WSJT. Its algorithm is
|
||||
patented, and the source code is the property of CodeVector
|
||||
Technologies, LLC. However, compiled versions of KVASD may be freely
|
||||
used in conjunction with WSJT for the purposes of amateur radio
|
||||
weak-signal communication.
|
||||
|
||||
|
||||
3 Some Functional Details
|
||||
----------------------------------------------------------------------
|
||||
WSJT execution starts at the top of Python file wsjt.py. The
|
||||
other Python modules are loaded and executed as needed. Fortran
|
||||
routines are called to start a high-priority thread to handle
|
||||
continuous A/D and D/A streams, and a background thread to decode
|
||||
received or previously recorded signals. The top-level Python
|
||||
code determines the overall state of program operation, e.g.,
|
||||
Idle, Monitoring, or Transmitting. In normal usage the operator
|
||||
puts the program into Auto mode, resulting in a timed sequence of
|
||||
alternating transmission and reception intervals.
|
||||
|
||||
|
||||
4 Other Open-Source Software used in WSJT
|
||||
----------------------------------------------------------------------
|
||||
WSJT 5.9 uses the following open source libraries:
|
||||
|
||||
1. FFTW, by Matteo Frigo and Steven Johnson, for computing Fourier
|
||||
transforms
|
||||
|
||||
2. PortAudio, by Ross Bencina and Phil Burk, for audio I/O
|
||||
|
||||
3. "Secret Rabbit Code" or "libsamplerate", by Erik de Castro, for
|
||||
accomplishing band-limited resampling of data
|
||||
|
||||
4. RS, by Phil Karn, KA9Q, for Reed Solomon encoding and
|
||||
hard-decision decoding.
|
||||
|
||||
|
||||
5 Platform-Dependent Notes
|
||||
----------------------------------------------------------------------
|
||||
The Python code should run on any supported Python platform. Most of
|
||||
the remaining code can be compiled for Linux, FreeBSD, unix, or OS/X,
|
||||
as well as Windows. Platform-dependent versions of FFTW, PortAudio,
|
||||
and libsamplerate may need to be installed.
|
||||
|
||||
Methods are provided for creating additional threads and setting their
|
||||
runtime priorities in Windows, Linux, and FreeBSD.
|
||||
|
||||
|
||||
6 Partial List of Functions and Subroutines, and their purposes
|
||||
----------------------------------------------------------------------
|
||||
Routines for audio startup, decoding, display computations
|
||||
blanker.f90 Noise blanker
|
||||
fivehz.f90 Called by PortAudio callback
|
||||
flat2.f Flatten the spectrum for waterfall display
|
||||
pix2d65.f90 Computes pixels for waterfall display
|
||||
pix2d.f90 Computes pixels for waterfall display
|
||||
runqqq.f90 Executes another process
|
||||
|
||||
wsjtgen.f90 Generates Tx waveforms
|
||||
abc441.f90 Part of FSK441 generator
|
||||
gen65.f Generate JT65 waveform
|
||||
chkmsg.f Check a JT65 message for presence of 'OOO'
|
||||
encode65.f Encode a JT65 message
|
||||
getpfx1.f Handle extra DXCC prefixes
|
||||
getpfx2.f ...
|
||||
graycode.f Convert binary to/from Gray code
|
||||
nchar.f Convert number, letter, space to 0-36
|
||||
packcall.f Routines for JT65 source encoding
|
||||
packdxcc.f ...
|
||||
packgrid.f ...
|
||||
packmsg.f ...
|
||||
packtext.f ...
|
||||
pfx.f ...
|
||||
gen6m.f Generate JT6M waveform
|
||||
gentone.f Generate tone for JT6M message
|
||||
gencw.f Generate CW waveform
|
||||
morse.f Convert ascii to morse dits
|
||||
gencwid.f Generate a CW ID message
|
||||
grid2k.f Convert grid locator to integer
|
||||
interleave63.f Interleave JT65 symbols
|
||||
|
||||
gcom1.f90 Global commons for sharing data among Fortran routines
|
||||
gcom2.f90 and between Fortran and Python
|
||||
gcom3.f90
|
||||
gcom4.f90
|
||||
|
||||
makedate.f90 Gererates makedate_sub.f90
|
||||
|
||||
Astronomical calculations:
|
||||
|
||||
astro.f Computes Az, El, Doppler for Sun, Moon, etc.
|
||||
astropak.f "Includes" for astro supoport routines
|
||||
azdist.f Computes azimuth, distance, etc., between two locators
|
||||
coord.f Spherical trig utility
|
||||
dcoord.f Spherical trig utility in double precision
|
||||
deg2grid.f Convert lat/long (degrees) to grid locator
|
||||
dot.f Compute dot product
|
||||
ftsky.f Get sky temperature from data file
|
||||
geocentric.f Convert geodetic to geocentric coords
|
||||
GeoDist.f Compute azimuth and distance between two locators
|
||||
grid2deg.f Convert grid locator to lat/long
|
||||
moon2.f Compute moon location at specified date and time
|
||||
MoonDop.f Compute lunar doppler shift and related quantities
|
||||
sun.f Compure sun location at specified date and time
|
||||
toxyz.f Convert between polar and cartesian coords
|
||||
|
||||
Utilities:
|
||||
db.f Compute decibels from ratio
|
||||
gasdev.f Generate Gaussian random numbers
|
||||
igray.f Gray code
|
||||
indexx.f Sort routine
|
||||
set.f Move, add, zero, ...
|
||||
pctile.f Sort an array and get specified percentile
|
||||
ran1.f Uniform random numbers
|
||||
rfile2.f Read a binary file (Linux)
|
||||
sort.f Sort an array
|
||||
|
||||
FFTs:
|
||||
fftw3.f Fortran definitions for FFTW
|
||||
four2a.f Wrapper to make FFTW look like four2
|
||||
four2.f FFT in Fortran (a;ternative to using FFTW)
|
||||
ps.f Compute power spectrum
|
||||
xfft.f Real to complex FFT wrapper
|
||||
|
||||
|
||||
Routines for Decoding:
|
||||
wsjt1.f Top-level decoding routine; handles FSK441 especially
|
||||
avesp2.f Computes average spectrum
|
||||
bzap.f Find and remove birdies
|
||||
detect.f Measure power in FSK441 tones
|
||||
flatten.f Flatten the spectrum
|
||||
longx.f Decode normal FSK441 messages
|
||||
lpf1.f Quick-and-dirty lowpass filter
|
||||
mtdecode.f Multi-tone decoding
|
||||
ping.f Find pings
|
||||
s2shape.f Flatten the 2d spectrum
|
||||
smooth.f Smooth by boxcar averaging
|
||||
spec2d.f Compute 2d spectrum for FSK441
|
||||
stdecode.f Decode FSK441 shorthand messages
|
||||
sync.f Synchronize FSK441 data
|
||||
|
||||
wsjt65.f JT65 decoder
|
||||
afc65.f AFC for JT65
|
||||
avemsg65.f Decode average message
|
||||
decode65.f Decode JT65 message
|
||||
deep65.f Deep search decoder
|
||||
demod64a.f Compute probabilities of transmitted symbols
|
||||
extract.f Extract message from JT65 symbol probabilities
|
||||
flat1.f Flatten the passband
|
||||
getsnr.f Compute snr or shorthand message
|
||||
k2grid.f Convert integer to 4-digit grid locator
|
||||
limit.f Clipper for JT65
|
||||
peakup.f Interpolate to find fractional-bin peak
|
||||
setup65.f Initialize pseudorandom sync vector
|
||||
short65.f Detect JT65 shorthand messages
|
||||
slope.f Remove a straight-line slope
|
||||
spec2d65.f Compute 2d spectrum for JT65
|
||||
spec441.f Compute spectra for FSK441 decoding
|
||||
sync65.f Synchronize a JT65 signal
|
||||
unpackcall.f Unpack JT65 message parts ...
|
||||
unpackgrid.f ...
|
||||
unpackmsg.f ...
|
||||
unpacktext.f ...
|
||||
xcor.f Compute cross-correlation for JT65 sync
|
||||
|
||||
decode6m.f Decode JT65 signal
|
||||
syncf0.f First frequency sync
|
||||
syncf1.f Second freq sync
|
||||
synct.f First time sync
|
||||
avemsg6m.f Get average JT65 message
|
||||
|
||||
JT65code.f Program to illustrate and test JT65 coding
|
||||
|
||||
Hard-Decision Reed Solomon Codec
|
||||
decode_rs.c Decoder
|
||||
encode_rs.c Encoder
|
||||
init_rs.c Initialization routine
|
||||
wrapkarn.c Wapper for Fortran
|
||||
|
||||
cutil.c Fortran wrappers for some basic C functions
|
||||
jtaudio.c Audio I/O, calls PortAudio routines
|
||||
padevsub.c Select desired audio device
|
||||
ptt.c PTT via serial port DTR/RTS
|
||||
ptt_linux.c Ditto for Linux (dummy at present)
|
||||
resample.c Wrapper for resample routine
|
||||
start_threads.c Start audio and decoder threads
|
||||
|
||||
|
||||
7 Compiling Instructions
|
||||
----------------------------------------------------------------------
|
||||
Scripts are provided for compiling WSJT in both Windows and Linux.
|
||||
They are presently set up to use Compaq Visual Fortran (v6.6) and
|
||||
Microsoft C (v6.0) in Windows, and g95 and gcc in Linux. My
|
||||
installation has Python 2.3. Additional tools include f2py, which
|
||||
compiles Fortran and C to make Python extensions; the Python Imaging
|
||||
Library; Numeric Python; and the SciPy distribution utilities.
|
||||
|
||||
Linux Windows Function
|
||||
-------------------------------------------------------------------
|
||||
g0 g0.bat Compiles the hard-decision Reed Solomon Decoder
|
||||
Needs to be done only once.
|
||||
g1 g1.bat Compiles the remaining Fortran and C to produce Python
|
||||
extension module audio.pyd (Windows) or audio.so
|
||||
(Linux).
|
||||
g2 g2.bat Uses McMillan Installer to create an f2py specification
|
||||
file, wsjt.spec
|
||||
g3 g3.bat Uses Installer to produce a distributable file WSJT6.EXE
|
||||
(Windows).
|
||||
g99 g99.bat Runs all of the g[0-3] scripts.
|
||||
|
||||
These steps produce a distributable file WSJT6.EXE (Windows) or wsjt6
|
||||
(Linux) that contains all necessary software components, so that the
|
||||
end user does not need to install Python or any of its other
|
||||
extensions, or the compilers.
|
||||
|
||||
A configuration script and Makefile facility is also provided.
|
||||
Assuming that all of the pre-requisites are properly installed, WSJT
|
||||
can now be compiled in Windows as follows:
|
||||
|
||||
C> copy Makefile.win Makefile
|
||||
C> nmake
|
||||
|
||||
In Linux or FreeBSD, do the following:
|
||||
|
||||
$ ./configure --enable-portaudio (or --enable-alsa or --enable-oss)
|
||||
$ make
|
||||
|
||||
|
||||
8 Present status (January 17, 2006)
|
||||
----------------------------------------------------------------------
|
||||
|
||||
WSJT version 5.9.2 (built from SVN revision 115) has been released for
|
||||
Windows. It is is fully functional in Linux and BSD, as well, but
|
||||
presently need to be compiled locally. In due course we plan to
|
||||
provide distributions for standard *nix distributions.
|
||||
|
||||
|
Binary file not shown.
30
abc441.F90
30
abc441.F90
@ -1,30 +0,0 @@
|
||||
subroutine abc441(msg,nmsg,itone,ndits)
|
||||
|
||||
character msg*28
|
||||
integer itone(84)
|
||||
integer lookup(0:91)
|
||||
character cc*43
|
||||
data cc/' 0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZ.,?/#$'/
|
||||
data lookup/13, 15, 17, 46, 47, 45, 44, 12, 11, 14, &
|
||||
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, &
|
||||
16, 48, 18, 19, 20, 21, 22, 23, 24, 25, &
|
||||
26, 27, 15, 29, 30, 14, 16, 42, 46, 35, &
|
||||
36, 37, 21, 0, 11, 41, 10, 13, 43, 1, &
|
||||
2, 3, 4, 5, 6, 7, 8, 9, 49, 56, &
|
||||
52, 55, 54, 12, 63, 17, 18, 19, 20, 44, &
|
||||
22, 23, 24, 25, 26, 27, 28, 29, 30, 31, &
|
||||
32, 33, 34, 35, 36, 37, 38, 39, 40, 41, &
|
||||
45, 63/
|
||||
save
|
||||
|
||||
do i=1,nmsg
|
||||
n=ichar(msg(i:i))
|
||||
if(n.lt.0 .or. n.gt.91) n=32 !Replace illegal char with blank
|
||||
n=lookup(n)
|
||||
itone(3*i-2)=n/16 + 1
|
||||
itone(3*i-1)=mod(n/4,4) + 1
|
||||
itone(3*i)=mod(n,4) + 1
|
||||
enddo
|
||||
ndits=3*nmsg
|
||||
return
|
||||
end subroutine abc441
|
110
avemsg6m.f
110
avemsg6m.f
@ -1,110 +0,0 @@
|
||||
subroutine avemsg6m(s2db,nz,nslim,NFixLen,cfile6,lcum,
|
||||
+ f0,lumsg,npkept)
|
||||
|
||||
C Attempts to find message length and then decodes an average message.
|
||||
|
||||
real s2db(0:43,nz)
|
||||
real s2dc(0:43,22)
|
||||
real wgt(22)
|
||||
real acf(0:430)
|
||||
logical lcum
|
||||
character*43 pua
|
||||
character*6 cfile6
|
||||
character*22 avemsg,blanks
|
||||
data pua/'0123456789., /#?$ABCDEFGHIJKLMNOPQRSTUVWXYZ'/
|
||||
data blanks/' '/
|
||||
data twopi/6.283185307/
|
||||
data offset/20.6/
|
||||
|
||||
C Adjustable sig limit, depending on length of data to average.
|
||||
nslim2=nslim - 9 + 4.0*log10(624.0/nz) !### +10 was here
|
||||
|
||||
k=0
|
||||
sum=0.
|
||||
nsum=0
|
||||
do j=1,nz
|
||||
if(mod(j,3).eq.1) then
|
||||
sum=sum+s2db(0,j) !Measure avg sig strength for sync tone
|
||||
nsum=nsum+1
|
||||
else
|
||||
k=k+1
|
||||
call move(s2db(0,j),s2db(0,k),44) !Save data spectra
|
||||
endif
|
||||
enddo
|
||||
sig=sum/nsum !Signal strength estimate
|
||||
nsig=nint(db(sig)-offset)
|
||||
|
||||
C Most of the time in this routine is in this loop.
|
||||
kz=k
|
||||
do lag=0,kz-1
|
||||
sum=0.
|
||||
do j=1,kz-lag
|
||||
do i=0,43
|
||||
sum=sum+s2db(i,j)*s2db(i,j+lag)
|
||||
enddo
|
||||
enddo
|
||||
acf(lag)=sum
|
||||
enddo
|
||||
acf0=acf(0)
|
||||
do lag=0,kz-1
|
||||
acf(lag)=acf(lag)/acf0
|
||||
enddo
|
||||
|
||||
lmsg1=NFixLen/256
|
||||
lmsg2=NFixLen-256*lmsg1
|
||||
if(mod(lmsg1,2).eq.1) lmsg1=lmsg1+1
|
||||
if(mod(lmsg2,2).eq.1) lmsg2=lmsg2+1
|
||||
smax=-1.e9
|
||||
do ip=4,22,2 !Compute periodogram for allowed msg periods
|
||||
if(NFixLen.ne.0 .and. ip.ne.4 .and. ip.ne.lmsg1
|
||||
+ .and. ip.ne.lmsg2) go to 5
|
||||
f=1.0/ip
|
||||
s=0.
|
||||
do lag=0,kz-1
|
||||
s=s+acf(lag)*cos(twopi*f*lag)
|
||||
enddo
|
||||
if(s.gt.smax) then
|
||||
smax=s
|
||||
msglen=ip !Save best message length
|
||||
endif
|
||||
5 enddo
|
||||
|
||||
C Average the symbols from s2db into s2dc.
|
||||
|
||||
call zero(s2dc,44*22)
|
||||
call zero(wgt,22)
|
||||
do j=1,kz
|
||||
k=mod(j-1,msglen)+1
|
||||
call add(s2db(0,j),s2dc(0,k),s2dc(0,k),44)
|
||||
wgt(k)=wgt(k)+1.0
|
||||
enddo
|
||||
|
||||
do j=1,msglen !Hard-decode the avg msg,
|
||||
smax=-1.e9 !picking max bin for each char
|
||||
do i=1,43
|
||||
s2dc(i,j)=s2dc(i,j)/wgt(j)
|
||||
if(s2dc(i,j).gt.smax) then
|
||||
smax=s2dc(i,j)
|
||||
ipk=i
|
||||
endif
|
||||
enddo
|
||||
k=mod(ipk,3)
|
||||
i=ipk
|
||||
avemsg(j:j)=pua(i:i)
|
||||
enddo
|
||||
ndf0=nint(f0-1076.66)
|
||||
do i=1,msglen
|
||||
if(avemsg(i:i).eq.' ') goto 10
|
||||
enddo
|
||||
go to 20
|
||||
10 avemsg=avemsg(i+1:msglen)//avemsg(1:i)
|
||||
20 if(nsig.gt.nslim2) then
|
||||
npkept=npkept+1
|
||||
avemsg=avemsg(1:msglen)//blanks
|
||||
write(lumsg,1020) cfile6,nsig,ndf0,avemsg,msglen
|
||||
if(lcum) write(21,1020) cfile6,nsig,ndf0,avemsg,msglen
|
||||
1020 format(a6,8x,i6,i5,7x,a22,19x,'*',i4)
|
||||
endif
|
||||
|
||||
return
|
||||
end
|
18
blanker.f90
18
blanker.f90
@ -1,18 +0,0 @@
|
||||
subroutine blanker(d2d,jz)
|
||||
|
||||
integer*2 d2d(jz)
|
||||
|
||||
avg=700.
|
||||
threshold=5.0
|
||||
do i=1,jz
|
||||
xmag=abs(d2d(i))
|
||||
xmed=0.75*xmed + 0.25*d2d(i)
|
||||
avg=0.999*avg + 0.001*xmag
|
||||
if(xmag.gt.threshold*avg) then
|
||||
! d2d(i)=nint(xmed)
|
||||
d2d(i)=0
|
||||
endif
|
||||
enddo
|
||||
|
||||
return
|
||||
end subroutine blanker
|
20
decode3.F90
20
decode3.F90
@ -37,8 +37,6 @@ subroutine decode3(d2,jz,istart,filename)
|
||||
d2d(i)=d2(i)
|
||||
enddo
|
||||
|
||||
if(nblank.ne.0) call blanker(d2d,jz)
|
||||
|
||||
nseg=1
|
||||
if(mode(1:4).eq.'JT65') then
|
||||
i=index(FileID,'.')-3
|
||||
@ -78,23 +76,7 @@ subroutine decode3(d2,jz,istart,filename)
|
||||
|
||||
nclearave=0
|
||||
nagain=0
|
||||
if(mode(1:4).eq.'JT65') then
|
||||
call pix2d65(d2d,jz)
|
||||
else if(mode.eq.'FSK441') then
|
||||
nz=s2(1,1)
|
||||
call pix2d(d2d,jz,mousebutton,MouseDF,NFreeze,mode,s2,64,nz,b)
|
||||
else if(mode(1:4).eq.'JT6M' .and. mousebutton.eq.0) then
|
||||
nz=s2(1,1)
|
||||
call pix2d(d2d,jz,mousebutton,MouseDF,NFreeze,mode,s2,64,nz,b)
|
||||
endif
|
||||
|
||||
! Compute red and magenta cutves for small plot area, FSK441/JT6M only
|
||||
if(mode.eq.'FSK441' .or. mode.eq.'JT6M') then
|
||||
do i=1,128
|
||||
if(mode.eq.'FSK441' .and. ps0(i).gt.0.0) ps0(i)=10.0*log10(ps0(i))
|
||||
if(psavg(i).gt.0.0) psavg(i)=10.0*log10(psavg(i))
|
||||
enddo
|
||||
endif
|
||||
call pix2d65(d2d,jz)
|
||||
|
||||
999 return
|
||||
end subroutine decode3
|
||||
|
159
decode6m.f
159
decode6m.f
@ -1,159 +0,0 @@
|
||||
subroutine decode6m(data,jz,cfile6,MinSigdB,istart,
|
||||
+ NFixLen,lcum,f0,lumsg,npkept,yellow)
|
||||
|
||||
C Decode a JT6M message. Data must start at the beginning of a
|
||||
C sync symbol; sync frequency is assumed to be f0.
|
||||
|
||||
parameter (NMAX=30*11025)
|
||||
real data(jz) !Raw data
|
||||
real s2db(0:43,646) !Spectra of symbols
|
||||
c real s2(128,646)
|
||||
real syncsig(646)
|
||||
real yellow(216)
|
||||
real ref(0:43)
|
||||
logical lcum
|
||||
character*43 pua
|
||||
character*48 msg
|
||||
character*6 cfile6
|
||||
real*8 dpha,twopi
|
||||
complex*16 z,dz
|
||||
complex zz
|
||||
complex ct(0:511)
|
||||
complex c
|
||||
common/hcom/c(NMAX)
|
||||
data pua/'0123456789., /#?$ABCDEFGHIJKLMNOPQRSTUVWXYZ'/
|
||||
data offset/20.6/
|
||||
|
||||
ps(zz)=real(zz)**2 + aimag(zz)**2 !Power spectrum function
|
||||
|
||||
C Convert data to baseband (complex result) using quadrature LO.
|
||||
twopi=8*atan(1.d0)
|
||||
dpha=twopi*f0/11025.d0
|
||||
dz=cmplx(cos(dpha),-sin(dpha))
|
||||
z=1.d0/dz
|
||||
do i=1,jz
|
||||
z=z*dz
|
||||
c(i)=data(i)*z
|
||||
enddo
|
||||
|
||||
C Get spectrum for each symbol.
|
||||
C NB: for decoding pings, could do FFTs first for sync intervals only,
|
||||
C and then for data symbols only where the sync amplitude is above
|
||||
C threshold. However, for the average message we want all FFTs computed.
|
||||
|
||||
call zero(ref,44)
|
||||
|
||||
nz=jz/512 - 1
|
||||
fac=1.0/512.0
|
||||
do j=1,nz
|
||||
i0=512*(j-1) + 1
|
||||
do i=0,511
|
||||
ct(i)=fac*c(i0+i)
|
||||
enddo
|
||||
call four2a(ct,512,1,-1,1)
|
||||
|
||||
C Save PS for each symbol
|
||||
do i=0,127
|
||||
xps=ps(ct(i))
|
||||
if(i.le.43) s2db(i,j)=xps
|
||||
c s2(i+1,j)=xps
|
||||
enddo
|
||||
if(mod(j,3).eq.1) call add(ref,s2db(0,j),ref,44) !Accumulate ref spec
|
||||
enddo
|
||||
|
||||
C Return sync-tone amplitudes for plotting.
|
||||
iz=nz/3 -1
|
||||
do i=1,iz
|
||||
j=3*i-2
|
||||
yellow(i)=s2db(0,j)-0.5*(s2db(0,j+1)+s2db(0,j+2))
|
||||
enddo
|
||||
yellow(216)=iz
|
||||
|
||||
fac=3.0/nz
|
||||
do i=0,43 !Normalize the ref spectrum
|
||||
ref(i)=fac*ref(i)
|
||||
enddo
|
||||
ref(0)=ref(2) !Sync bin uses bin 2 as ref
|
||||
|
||||
do j=1,nz !Compute strength of sync
|
||||
m=mod(j-1,3) !signal at each j.
|
||||
ja=j-m-3
|
||||
jb=ja+3
|
||||
if(ja.lt.1) ja=ja+3
|
||||
if(jb.gt.nz) jb=jb-3
|
||||
syncsig(j)=0.5*(s2db(0,ja)+s2db(0,jb))/ref(0)
|
||||
syncsig(j)=db(syncsig(j)) - offset
|
||||
do i=0,43 !Normalize s2db
|
||||
s2db(i,j)=s2db(i,j)/ref(i)
|
||||
enddo
|
||||
enddo
|
||||
|
||||
C Decode any message of 2 or more consecutive characters bracketed by
|
||||
C sync-tones above a threshold.
|
||||
C Use hard-decoding (i.e., pick max bin).
|
||||
|
||||
nslim=MinSigdB !Signal limit for decoding
|
||||
ndf0=nint(f0-1076.77) !Freq offset DF, in Hz
|
||||
n=0 !Number of decoded characters
|
||||
j0=0
|
||||
sbest=-1.e9
|
||||
do j=2,nz-1,3
|
||||
if(syncsig(j).ge.float(nslim)) then
|
||||
|
||||
C Is it time to write out the results?
|
||||
if((n.eq.48) .or. (j.ne.j0+3 .and. j0.ne.0)) then
|
||||
nsig=nint(sbest)
|
||||
width=(512./11025.)*(1.5*n+1.0)
|
||||
if(nsig.ge.nslim) then
|
||||
npkept=npkept+1
|
||||
write(lumsg,1010) cfile6,tping,width,
|
||||
+ nsig,ndf0,(msg(k:k),k=1,n)
|
||||
if(lcum) write(21,1010) cfile6,tping,width,
|
||||
+ nsig,ndf0,(msg(k:k),k=1,n)
|
||||
1010 format(a6,2f5.1,i4,i5,6x,48a1) !### 6x was 7x ###
|
||||
endif
|
||||
n=0
|
||||
sbest=-1.e9
|
||||
endif
|
||||
j0=j
|
||||
smax1=-1.e9
|
||||
do i=1,43 !Pick max bin for 1st char
|
||||
if(s2db(i,j).gt.smax1) then
|
||||
smax1=s2db(i,j)
|
||||
ipk=i
|
||||
endif
|
||||
enddo
|
||||
n=n+1
|
||||
if(n.eq.1) tping=j*512./11025. + (istart-1)/11025.0 !Start of ping
|
||||
msg(n:n)=pua(ipk:ipk) !Decoded character
|
||||
|
||||
smax2=-1.e9
|
||||
do i=1,43
|
||||
if(s2db(i,j+1).gt.smax2) then
|
||||
smax2=s2db(i,j+1)
|
||||
ipk=i
|
||||
endif
|
||||
enddo
|
||||
n=n+1
|
||||
msg(n:n)=pua(ipk:ipk)
|
||||
sig0=10.0**(0.1*(syncsig(j)+offset))
|
||||
sig=db(0.5*sig0 + 0.25*(smax1+smax2))-offset
|
||||
sbest=max(sbest,sig)
|
||||
endif
|
||||
enddo
|
||||
|
||||
nsig=nint(sbest)
|
||||
width=(512./11025.)*(1.5*n+1.0)
|
||||
if(n.ne.0 .and. nsig.ge.nslim) then
|
||||
npkept=npkept+1
|
||||
write(lumsg,1010) cfile6,tping,
|
||||
+ width,nsig,ndf0,(msg(k:k),k=1,n)
|
||||
if(lcum) write(21,1010) cfile6,tping,
|
||||
+ width,nsig,ndf0,(msg(k:k),k=1,n)
|
||||
endif
|
||||
|
||||
C Decode average message for the whole record.
|
||||
call avemsg6m(s2db,nz,nslim,NFixLen,cfile6,lcum,f0,lumsg,npkept)
|
||||
|
||||
return
|
||||
end
|
3
g0
3
g0
@ -1,3 +0,0 @@
|
||||
gcc -c -DBIGSYM=1 init_rs.c
|
||||
gcc -c -DBIGSYM=1 encode_rs.c
|
||||
gcc -c -DBIGSYM=1 decode_rs.c
|
5
g1
5
g1
@ -1,5 +0,0 @@
|
||||
G95=/usr/local/bin/g95
|
||||
COMPILER=//usr/local/lib/gcc-lib/i386-unknown-freebsd5.4/4.0.1/
|
||||
python f2py.py -c --quiet --opt="-O -cpp -DFreeBSD -fno-second-underscore" init_rs.o encode_rs.o decode_rs.o -m Audio --f77exec=$G95 --f90exec=$G95 -L$COMPILER -lpthread -lg2c only: ftn_init ftn_quit audio_init spec getfile azdist0 astro0 : a2d.f90 abc441.f90 astro0.f90 audio_init.f90 azdist0.f90 blanker.f90 decode1.f90 decode2.f90 decode3.f90 ftn_init.f90 ftn_quit.f90 get_fname.f90 getfile.f90 horizspec.f90 hscroll.f90 i1tor4.f90 pix2d.f90 pix2d65.f90 rfile.f90 savedata.f90 spec.f90 wsjtgen.f90 runqqq.f90 wsjt1.f fsubs1.f fsubs.f astro.f astropak.f jtaudio.c ptt_bsd.c igray.c wrapkarn.c start_threads.c cutil.c fivehz.f90
|
||||
|
||||
|
49
gen6m.f
49
gen6m.f
@ -1,49 +0,0 @@
|
||||
subroutine gen6m(msg,samfac,iwave,nwave)
|
||||
|
||||
C Encodes a message into a wavefile for transmitting JT6M signals.
|
||||
|
||||
parameter (NMAX=21504) !NMAX=28*512*3/2: number of waveform samples
|
||||
character*28 msg !Message to be generated
|
||||
real*8 samfac
|
||||
real*4 x(NMAX) !Data for wavefile
|
||||
integer*2 iwave(NMAX) !Generated wave file
|
||||
integer*4 imsg(28)
|
||||
|
||||
do i=27,1,-1 !Get message length
|
||||
if(msg(i:i).ne.' ') go to 10
|
||||
enddo
|
||||
i=1
|
||||
10 nmsg=i+1
|
||||
if(mod(nmsg,2).eq.1) nmsg=nmsg+1 !Make it even
|
||||
|
||||
nwave=nmsg*512*3/2
|
||||
do m=1,nmsg !Get character code numbers
|
||||
ic=m
|
||||
n=ichar(msg(ic:ic))
|
||||
C Calculate i in range 0-42:
|
||||
if(n.ge.ichar('0') .and. n.le.ichar('9')) i=n-ichar('0')
|
||||
if(msg(ic:ic).eq.'.') i=10
|
||||
if(msg(ic:ic).eq.',') i=11
|
||||
if(msg(ic:ic).eq.' ') i=12
|
||||
if(msg(ic:ic).eq.'/') i=13
|
||||
if(msg(ic:ic).eq.'#') i=14
|
||||
if(msg(ic:ic).eq.'?') i=15
|
||||
if(msg(ic:ic).eq.'$') i=16
|
||||
if(n.ge.ichar('a') .and. n.le.ichar('z')) i=n-ichar('a')+17
|
||||
if(n.ge.ichar('A') .and. n.le.ichar('Z')) i=n-ichar('A')+17
|
||||
imsg(m)=i
|
||||
enddo
|
||||
|
||||
k=1
|
||||
do i=1,nmsg,2
|
||||
call gentone(x(k),-1,k) !Generate a sync tone
|
||||
call gentone(x(k),imsg(i),k) !First character
|
||||
call gentone(x(k),imsg(i+1),k) !Second character
|
||||
enddo
|
||||
|
||||
do i=1,nwave
|
||||
iwave(i)=nint(32767.0*x(i))
|
||||
enddo
|
||||
|
||||
return
|
||||
end
|
92
glpr
92
glpr
@ -1,92 +0,0 @@
|
||||
lpr astro.f
|
||||
lpr Audio.f90
|
||||
lpr avemsg65.f
|
||||
lpr avemsg6m.f
|
||||
lpr avesp2.f
|
||||
lpr azdist.f
|
||||
lpr bzap.f
|
||||
lpr chkmsg.f
|
||||
lpr coord.f
|
||||
lpr db.f
|
||||
lpr dcoord.f
|
||||
lpr decode65.f
|
||||
lpr decode6m.f
|
||||
lpr deep65.f
|
||||
lpr deg2grid.f
|
||||
lpr demod64a.f
|
||||
lpr detect.f
|
||||
lpr dot.f
|
||||
lpr encode65.f
|
||||
lpr extract.f
|
||||
lpr fivehz.f90
|
||||
lpr flat1.f
|
||||
lpr flat2.f
|
||||
lpr flatten.f
|
||||
lpr four2a.f
|
||||
lpr fsubs1.f
|
||||
lpr fsubs.f
|
||||
lpr ftsky.f
|
||||
lpr gasdev.f
|
||||
lpr gen65.f
|
||||
lpr gen6m.f
|
||||
lpr gencw.f
|
||||
lpr gentone.f
|
||||
lpr geocentric.f
|
||||
lpr geodist.f
|
||||
lpr getpfx1.f
|
||||
lpr getpfx2.f
|
||||
lpr getsnr.f
|
||||
lpr graycode.f
|
||||
lpr grid2deg.f
|
||||
lpr grid2k.f
|
||||
lpr igray.f
|
||||
lpr indexx.f
|
||||
lpr interleave63.f
|
||||
lpr jtaudio.c
|
||||
lpr k2grid.f
|
||||
lpr limit.f
|
||||
lpr longx.f
|
||||
lpr lpf1.f
|
||||
lpr moon2.f
|
||||
lpr MoonDop.f
|
||||
lpr morse.f
|
||||
lpr mtdecode.f
|
||||
lpr nchar.f
|
||||
lpr packcall.f
|
||||
lpr packgrid.f
|
||||
lpr packmsg.f
|
||||
lpr packtext.f
|
||||
lpr pctile.f
|
||||
lpr peakup.f
|
||||
lpr ping.f
|
||||
lpr ps.f
|
||||
lpr ptt.c
|
||||
lpr ran1.f
|
||||
lpr resample.c
|
||||
lpr s2shape.f
|
||||
lpr set.f
|
||||
lpr setup65.f
|
||||
lpr short65.f
|
||||
lpr slope.f
|
||||
lpr smooth.f
|
||||
lpr sort.f
|
||||
lpr spec2d65.f
|
||||
lpr spec2d.f
|
||||
lpr spec441.f
|
||||
lpr stdecode.f
|
||||
lpr sun.f
|
||||
lpr sync65.f
|
||||
lpr sync.f
|
||||
lpr syncf0.f
|
||||
lpr syncf1.f
|
||||
lpr synct.f
|
||||
lpr toxyz.f
|
||||
lpr unpackcall.f
|
||||
lpr unpackgrid.f
|
||||
lpr unpackmsg.f
|
||||
lpr unpacktext.f
|
||||
lpr wrapkarn.c
|
||||
lpr wsjt1.f
|
||||
lpr wsjt65.f
|
||||
lpr xcor.f
|
||||
lpr xfft.f
|
3
go
3
go
@ -1,3 +0,0 @@
|
||||
gcc -c wrapkarn.c
|
||||
gcc -c igray.c
|
||||
f77 -o JT65code -fno-second-underscore JT65code_all.f igray.o wrapkarn.o init_rs.o encode_rs.o decode_rs.o
|
@ -1,88 +0,0 @@
|
||||
|
||||
!------------------------------------------------------ horizspec
|
||||
subroutine horizspec(x,brightness,contrast,a)
|
||||
|
||||
real x(4096)
|
||||
integer brightness,contrast
|
||||
integer*2 a(750,300)
|
||||
real y(512),ss(128)
|
||||
complex c(0:256)
|
||||
equivalence (y,c)
|
||||
include 'gcom1.f90'
|
||||
include 'gcom2.f90'
|
||||
save
|
||||
|
||||
nfft=512
|
||||
nq=nfft/4
|
||||
gain=50.0 * 3.0**(0.36+0.01*contrast)
|
||||
offset=0.5*(brightness+30.0)
|
||||
df=11025.0/512.0
|
||||
if(ntr.ne.ntr0) then
|
||||
if(lauto.eq.0 .or. ntr.eq.TxFirst) then
|
||||
call hscroll(a,nx)
|
||||
nx=0
|
||||
endif
|
||||
ntr0=ntr
|
||||
endif
|
||||
|
||||
i0=0
|
||||
do iter=1,5
|
||||
if(nx.lt.750) nx=nx+1
|
||||
do i=1,nfft
|
||||
y(i)=1.4*x(i+i0)
|
||||
enddo
|
||||
call xfft2(y,nfft)
|
||||
nq=nfft/4
|
||||
do i=1,nq
|
||||
ss(i)=real(c(i))**2 + aimag(c(i))**2
|
||||
enddo
|
||||
|
||||
p=0.
|
||||
do i=21,120
|
||||
p=p+ss(i)
|
||||
n=0
|
||||
if(ss(i).gt.0.) n=gain*log10(0.05*ss(i)) + offset
|
||||
n=min(252,max(0,n))
|
||||
j=121-i
|
||||
a(nx,j)=n
|
||||
enddo
|
||||
if(nx.eq.7 .or. nx.eq.378 .or. nx.eq.750) then
|
||||
! Put in yellow ticks at the standard tone frequencies for FSK441, or
|
||||
! at the sync-tone frequency for JT65, JT6M.
|
||||
do i=nx-4,nx
|
||||
if(mode.eq.'FSK441') then
|
||||
do n=2,5
|
||||
j=121-nint(n*441/df)
|
||||
a(i,j)=254
|
||||
enddo
|
||||
else if(mode(1:4).eq.'JT65') then
|
||||
j=121-nint(1270.46/df)
|
||||
a(i,j)=254
|
||||
else if(mode.eq.'JT6M') then
|
||||
j=121-nint(1076.66/df)
|
||||
a(i,j)=254
|
||||
endif
|
||||
enddo
|
||||
endif
|
||||
|
||||
ng=140 - 30*log10(0.00033*p+0.001)
|
||||
ng=min(ng,150)
|
||||
if(nx.eq.1) ng0=ng
|
||||
if(abs(ng-ng0).le.1) then
|
||||
a(nx,ng)=255
|
||||
else
|
||||
ist=1
|
||||
if(ng.lt.ng0) ist=-1
|
||||
jmid=(ng+ng0)/2
|
||||
i=max(1,nx-1)
|
||||
do j=ng0+ist,ng,ist
|
||||
a(i,j)=255
|
||||
if(j.eq.jmid) i=i+1
|
||||
enddo
|
||||
ng0=ng
|
||||
endif
|
||||
i0=i0+441
|
||||
enddo
|
||||
|
||||
return
|
||||
end subroutine horizspec
|
14
hscroll.f90
14
hscroll.f90
@ -1,14 +0,0 @@
|
||||
|
||||
!------------------------------------------------- hscroll
|
||||
subroutine hscroll(a,nx)
|
||||
integer*2 a(750,300)
|
||||
|
||||
do j=1,150
|
||||
do i=1,750
|
||||
if(nx.gt.50) a(i,150+j)=a(i,j)
|
||||
a(i,j)=0
|
||||
enddo
|
||||
enddo
|
||||
return
|
||||
|
||||
end subroutine hscroll
|
128
longx.f
128
longx.f
@ -1,128 +0,0 @@
|
||||
subroutine longx(dat,npts0,ps,DFTolerance,noffset,
|
||||
+ msg,msglen,bauderr)
|
||||
|
||||
C Look for 441-baud modulation, synchronize to it, and decode message.
|
||||
C Longest allowed data analysis is 1 second.
|
||||
|
||||
parameter (NMAX=11025)
|
||||
parameter (NDMAX=NMAX/25)
|
||||
real dat(npts0)
|
||||
real ps(128),psmo(20)
|
||||
integer DFTolerance
|
||||
real y1(NMAX)
|
||||
real y2(NMAX)
|
||||
real y3(NMAX)
|
||||
real y4(NMAX)
|
||||
real wgt(-2:2)
|
||||
integer dit(NDMAX)
|
||||
integer n4(0:2)
|
||||
character msg*40
|
||||
character c*48
|
||||
common/acom/a1,a2,a3,a4
|
||||
data c/' 123456789.,?/# $ABCD FGHIJKLMNOPQRSTUVWXY 0EZ '/
|
||||
data wgt/1.0,4.0,6.0,4.0,1.0/
|
||||
|
||||
NSPD=25 !Change if FSK110 is implemented
|
||||
LTone=2
|
||||
NBaud=11025/NSPD
|
||||
npts=min(NMAX,npts0)
|
||||
df=11025.0/256.0
|
||||
smax=0.
|
||||
|
||||
C Find the frequency offset of this ping.
|
||||
C NB: this might be improved by including a bandpass correction to ps.
|
||||
|
||||
ia=nint((LTone*NBaud-DFTolerance)/df)
|
||||
ib=nint((LTone*NBaud+DFTolerance)/df)
|
||||
|
||||
do i=ia,ib !Search for correct DF
|
||||
sum=0.
|
||||
do j=1,4 !Sum over the 4 tones
|
||||
m=nint((i*df+(j-1)*NBaud)/df)
|
||||
do k=-2,2 !Weighted averages over 5 bins
|
||||
sum=sum+wgt(k)*ps(m+k)
|
||||
enddo
|
||||
enddo
|
||||
k=i-ia+1
|
||||
psmo(k)=sum
|
||||
kpk=0
|
||||
if(sum.gt.smax) then
|
||||
smax=sum
|
||||
noffset=nint(i*df-LTone*NBaud)
|
||||
kpk=k
|
||||
endif
|
||||
enddo
|
||||
|
||||
|
||||
if(kpk.gt.1 .and. kpk.lt.20) then
|
||||
call peakup(psmo(kpk-1),psmo(kpk),psmo(kpk+1),dx)
|
||||
noffset=nint(noffset+dx*df)
|
||||
endif
|
||||
|
||||
C Do square-law detection in each of four filters.
|
||||
f1=LTone*NBaud+noffset
|
||||
f2=(LTone+1)*NBaud+noffset
|
||||
f3=(LTone+2)*NBaud+noffset
|
||||
f4=(LTone+3)*NBaud+noffset
|
||||
call detect(dat,npts,f1,y1)
|
||||
call detect(dat,npts,f2,y2)
|
||||
call detect(dat,npts,f3,y3)
|
||||
call detect(dat,npts,f4,y4)
|
||||
|
||||
C Bandpass correction:
|
||||
npts=npts-(NSPD-1)
|
||||
do i=1,npts
|
||||
y1(i)=y1(i)*a1
|
||||
y2(i)=y2(i)*a2
|
||||
y3(i)=y3(i)*a3
|
||||
y4(i)=y4(i)*a4
|
||||
enddo
|
||||
|
||||
call sync(y1,y2,y3,y4,npts,jpk,baud,bauderr)
|
||||
|
||||
C Decimate y arrays by NSPD
|
||||
ndits=npts/NSPD - 1
|
||||
do i=1,ndits
|
||||
y1(i)=y1(jpk+(i-1)*NSPD)
|
||||
y2(i)=y2(jpk+(i-1)*NSPD)
|
||||
y3(i)=y3(jpk+(i-1)*NSPD)
|
||||
y4(i)=y4(jpk+(i-1)*NSPD)
|
||||
enddo
|
||||
|
||||
C Now find the mod3 phase that has no tone 3's
|
||||
n4(0)=0
|
||||
n4(1)=0
|
||||
n4(2)=0
|
||||
do i=1,ndits
|
||||
ymax=max(y1(i),y2(i),y3(i),y4(i))
|
||||
if(y1(i).eq.ymax) dit(i)=0
|
||||
if(y2(i).eq.ymax) dit(i)=1
|
||||
if(y3(i).eq.ymax) dit(i)=2
|
||||
if(y4(i).eq.ymax) then
|
||||
dit(i)=3
|
||||
k=mod(i,3)
|
||||
n4(k)=n4(k)+1
|
||||
endif
|
||||
enddo
|
||||
|
||||
n4min=min(n4(0),n4(1),n4(2))
|
||||
if(n4min.eq.n4(0)) jsync=3
|
||||
if(n4min.eq.n4(1)) jsync=1
|
||||
if(n4min.eq.n4(2)) jsync=2
|
||||
C Might want to notify if n4min>0 or if one of the others is equal
|
||||
C to n4min. In both cases, could then decode 2 or 3 times, using
|
||||
C other starting phases.
|
||||
|
||||
C Finally, decode the message.
|
||||
msg=' '
|
||||
msglen=ndits/3
|
||||
msglen=min(msglen,40)
|
||||
do i=1,msglen
|
||||
j=(i-1)*3+jsync
|
||||
nc=16*dit(j) + 4*dit(j+1) +dit(j+2)
|
||||
msg(i:i)=' '
|
||||
if(nc.le.47) msg(i:i)=c(nc+1:nc+1)
|
||||
enddo
|
||||
|
||||
return
|
||||
end
|
144
mtdecode.f
144
mtdecode.f
@ -1,144 +0,0 @@
|
||||
subroutine mtdecode(dat,jz,nz,MinSigdB,MinWidth,
|
||||
+ NQRN,DFTolerance,istart,pick,cfile6,ps0)
|
||||
|
||||
C Decode Multi-Tone FSK441 mesages.
|
||||
|
||||
real dat(jz) !Raw audio data
|
||||
integer NQRN
|
||||
integer DFTolerance
|
||||
logical pick
|
||||
character*6 cfile6,cf*1
|
||||
|
||||
real sigdb(3100) !Detected signal in dB, sampled at 20 ms
|
||||
real work(3100)
|
||||
integer indx(3100)
|
||||
real pingdat(3,100)
|
||||
real ps(128)
|
||||
real ps0(128)
|
||||
character msg*40,msg3*3
|
||||
character*90 line
|
||||
common/ccom/nline,tping(100),line(100)
|
||||
|
||||
slim=MinSigdB
|
||||
wmin=0.001*MinWidth * (19.95/20.0)
|
||||
nf1=-DFTolerance
|
||||
nf2=DFTolerance
|
||||
msg3=' '
|
||||
dt=1.0/11025.0
|
||||
|
||||
C Find signal power at suitable intervals to search for pings.
|
||||
istep=221
|
||||
dtbuf=istep/11025.
|
||||
do n=1,nz
|
||||
s=0.
|
||||
ib=n*istep
|
||||
ia=ib-istep+1
|
||||
do i=ia,ib
|
||||
s=s+dat(i)**2
|
||||
enddo
|
||||
sigdb(n)=s/istep
|
||||
enddo
|
||||
|
||||
!#####################################################################
|
||||
if(.not.pick) then
|
||||
! Remove initial transient from sigdb
|
||||
call indexx(nz,sigdb,indx)
|
||||
imax=0
|
||||
do i=1,50
|
||||
if(indx(i).gt.50) go to 10
|
||||
imax=max(imax,indx(i))
|
||||
enddo
|
||||
10 do i=1,50
|
||||
if(indx(nz+1-i).gt.50) go to 20
|
||||
imax=max(imax,indx(nz+1-i))
|
||||
enddo
|
||||
20 imax=imax+6 !Safety margin
|
||||
base1=sigdb(indx(nz/2))
|
||||
do i=1,imax
|
||||
sigdb(i)=base1
|
||||
enddo
|
||||
endif
|
||||
!##################################################################
|
||||
|
||||
call smooth(sigdb,nz)
|
||||
|
||||
C Remove baseline and one dB for good measure.
|
||||
call pctile (sigdb,work,nz,50,base1)
|
||||
do i=1,nz
|
||||
sigdb(i)=dB(sigdb(i)/base1) - 1.0
|
||||
enddo
|
||||
|
||||
call ping(sigdb,nz,dtbuf,slim,wmin,pingdat,nping)
|
||||
|
||||
C If this is a "mouse pick" and no ping was found, force a pseudo-ping
|
||||
C at center of data.
|
||||
if(pick.and.nping.eq.0) then
|
||||
if(nping.le.99) nping=nping+1
|
||||
pingdat(1,nping)=0.5*jz*dt
|
||||
pingdat(2,nping)=0.16
|
||||
pingdat(3,nping)=1.0
|
||||
endif
|
||||
|
||||
bigpeak=0.
|
||||
do iping=1,nping
|
||||
C Find starting place and length of data to be analyzed:
|
||||
tstart=pingdat(1,iping)
|
||||
width=pingdat(2,iping)
|
||||
peak=pingdat(3,iping)
|
||||
mswidth=10*nint(100.0*width)
|
||||
jj=(tstart-0.02)/dt
|
||||
if(jj.lt.1) jj=1
|
||||
jjz=nint((width+0.02)/dt)+1
|
||||
jjz=min(jjz,jz+1-jj)
|
||||
|
||||
C Compute average spectrum of this ping.
|
||||
call spec441(dat(jj),jjz,ps,f0)
|
||||
|
||||
C Decode the message.
|
||||
msg=' '
|
||||
call longx(dat(jj),jjz,ps,DFTolerance,noffset,msg,
|
||||
+ msglen,bauderr)
|
||||
qrnlimit=4.4*1.5**(5.0-NQRN)
|
||||
if(NQRN.eq.0) qrnlimit=99.
|
||||
if(msglen.eq.0) go to 100
|
||||
|
||||
C Assemble a signal report:
|
||||
nwidth=0
|
||||
if(width.ge.0.04) nwidth=1 !These might depend on NSPD
|
||||
if(width.ge.0.12) nwidth=2
|
||||
if(width.gt.1.00) nwidth=3
|
||||
nstrength=6
|
||||
if(peak.ge.11.0) nstrength=7
|
||||
if(peak.ge.17.0) nstrength=8
|
||||
if(peak.ge.23.0) nstrength=9
|
||||
|
||||
! if(peak.gt.5.0 .and.mswidth.ge.100) then
|
||||
! call specsq(dat(jj),jjz,DFTolerance,0,noffset2)
|
||||
! noffset=noffset2
|
||||
! endif
|
||||
|
||||
C Discard this ping if DF outside tolerance limits or bauderr too big.
|
||||
C (However, if the ping was mouse-picked, proceed anyway.)
|
||||
|
||||
if(.not.pick .and. ((noffset.lt.nf1 .or. noffset.gt.nf2) .or.
|
||||
+ (abs(bauderr).gt.qrnlimit))) goto 100
|
||||
|
||||
C If it's the best ping yet, save the spectrum:
|
||||
if(peak.gt.bigpeak) then
|
||||
bigpeak=peak
|
||||
do i=1,128
|
||||
ps0(i)=ps(i)
|
||||
enddo
|
||||
endif
|
||||
|
||||
tstart=tstart + dt*(istart-1)
|
||||
cf=' '
|
||||
if(nline.le.99) nline=nline+1
|
||||
tping(nline)=tstart
|
||||
write(line(nline),1050) cfile6,tstart,mswidth,int(peak),
|
||||
+ nwidth,nstrength,noffset,msg3,msg,cf
|
||||
1050 format(a6,f5.1,i5,i3,1x,2i1,i5,1x,a3,1x,a40,1x,a1)
|
||||
100 enddo
|
||||
|
||||
return
|
||||
end
|
136
pix2d.f90
136
pix2d.f90
@ -1,136 +0,0 @@
|
||||
subroutine pix2d(d2,jz,mousebutton,mousedf,nfreeze,mode,s2,nchan,nz,b)
|
||||
|
||||
! Compute pixels to represent the 2-d spectrum s2(nchan,nz), and the
|
||||
! green line.
|
||||
|
||||
integer*2 d2(jz) !Raw input data
|
||||
character*6 mode
|
||||
real s2(nchan,nz) !2-d spectrum
|
||||
integer*2 b(60000) !Pixels corresponding to 2-d spectrum
|
||||
data nx0/0/
|
||||
save
|
||||
|
||||
tbest=s2(2,1)
|
||||
s2(1,1)=s2(3,1)
|
||||
s2(2,1)=s2(3,1)
|
||||
|
||||
gain=100.
|
||||
offset=0.0
|
||||
|
||||
if(mousebutton.eq.0) then
|
||||
k=0
|
||||
do i=54,7,-1
|
||||
do j=1,nz
|
||||
k=k+1
|
||||
n=0
|
||||
if(s2(i,j).gt.0) n=gain*log10(s2(i,j)) + offset
|
||||
n=min(252,max(0,n))
|
||||
b(k)=n
|
||||
enddo
|
||||
k=k+500-nz
|
||||
enddo
|
||||
do i=k+1,60000
|
||||
b(i)=0
|
||||
enddo
|
||||
|
||||
else
|
||||
! This is a mouse-picked decode, so we compute the "zoomed" region.
|
||||
k=50*500
|
||||
do i=54,7,-1
|
||||
do j=1,nz
|
||||
k=k+1
|
||||
n=0
|
||||
if(s2(i,j).gt.0) n=gain*log10(s2(i,j)) + offset
|
||||
n=min(252,max(0,n))
|
||||
b(k)=n
|
||||
enddo
|
||||
k=k+500-nz
|
||||
enddo
|
||||
endif
|
||||
|
||||
if(mousebutton.eq.0) then
|
||||
! Compute the green curve
|
||||
sum=0.
|
||||
do i=1,jz
|
||||
sum=sum+d2(i)
|
||||
enddo
|
||||
nave=nint(sum/jz)
|
||||
nadd=661
|
||||
ngreen=min(jz/nadd,500)
|
||||
k=0
|
||||
j=0
|
||||
do i=1,ngreen
|
||||
sq=0.
|
||||
do n=1,nadd
|
||||
k=k+1
|
||||
d2(k)=d2(k)-nave
|
||||
x=d2(k)
|
||||
sq=sq + x*x
|
||||
enddo
|
||||
x=0.0001*sq/nadd
|
||||
j=j+1
|
||||
x=120.0-40.0*log10(0.01*x)
|
||||
if(x.lt.1.0) x=1.0
|
||||
if(x.gt.119.) x=119.
|
||||
ng=nint(x)
|
||||
ng=min(ng,120)
|
||||
nx=i
|
||||
if(nx.eq.1) ng0=ng
|
||||
if(abs(ng-ng0).le.1) then
|
||||
b((ng-1)*500+nx)=255
|
||||
else
|
||||
ist=1
|
||||
if(ng.lt.ng0) ist=-1
|
||||
jmid=(ng+ng0)/2
|
||||
ii=max(1,nx-1)
|
||||
do j=ng0+ist,ng,ist
|
||||
b((j-1)*500+ii)=255
|
||||
if(j.eq.jmid) ii=ii+1
|
||||
enddo
|
||||
ng0=ng
|
||||
endif
|
||||
enddo
|
||||
|
||||
if(mode.eq.'FSK441') then
|
||||
! Insert yellow tick marks at frequencies of the FSK441 tones
|
||||
do i=2,5
|
||||
f=441*i
|
||||
ich=58-nint(f/43.066)
|
||||
do j=1,5
|
||||
b((ich-1)*500+j+2)=254
|
||||
b((ich-1)*500+j+248)=254
|
||||
b((ich-1)*500+j+495)=254
|
||||
enddo
|
||||
enddo
|
||||
else if(mode.eq.'JT6M') then
|
||||
! Insert yellow tick marks at frequencies of the JT6M sync tone
|
||||
f=1076.66
|
||||
ich=60-nint(f/43.066) !Why 58 for FSK441, above?
|
||||
do j=1,5
|
||||
b((ich-1)*500+j+2)=254
|
||||
b((ich-1)*500+j+248)=254
|
||||
b((ich-1)*500+j+495)=254
|
||||
enddo
|
||||
! Insert green tick at frequency indicated by MouseDF
|
||||
if(NFreeze.gt.0) then
|
||||
f=1076.66+mousedf
|
||||
ich=60-nint(f/43.066) !Why 58 for FSK441, above?
|
||||
do j=1,7
|
||||
b((ich-1)*500+j+2)=255
|
||||
enddo
|
||||
endif
|
||||
endif
|
||||
|
||||
! Mark the best ping with a red tick
|
||||
if(tbest.gt.0.0) then
|
||||
nx=tbest/0.060 + 1
|
||||
do j=110,120
|
||||
b((j-1)*500+nx0)=0
|
||||
b((j-1)*500+nx)=253
|
||||
enddo
|
||||
nx0=nx
|
||||
endif
|
||||
endif
|
||||
|
||||
return
|
||||
end subroutine pix2d
|
18
spec.f90
18
spec.f90
@ -63,10 +63,6 @@ subroutine spec(brightness,contrast,logmap,ngain,nspeed,a)
|
||||
npts=jzc/2048
|
||||
npts=2048*npts
|
||||
kread=0
|
||||
if(nspeed.ge.6) then
|
||||
call hscroll(a,nx)
|
||||
nx=0
|
||||
endif
|
||||
endif
|
||||
if(npts.lt.0) npts=npts+nmax
|
||||
if(npts.lt.nfft) go to 900 !Not enough data available
|
||||
@ -118,20 +114,6 @@ subroutine spec(brightness,contrast,logmap,ngain,nspeed,a)
|
||||
endif
|
||||
endif
|
||||
|
||||
if(nspeed.ge.6) then
|
||||
call horizspec(x,brightness,contrast,a)
|
||||
ncall=Mod(ncall+1,5)
|
||||
if(ncall.eq.1 .or. nspeed.eq.7) newdat=1
|
||||
if(ndiskdat.eq.1) then
|
||||
npts=jzc-kread
|
||||
else
|
||||
npts=iwrite-iread
|
||||
if(npts.lt.0) npts=npts+nmax
|
||||
endif
|
||||
if(npts.ge.4096) go to 10
|
||||
go to 900
|
||||
endif
|
||||
|
||||
call xfft2(x,nfft)
|
||||
|
||||
do i=1,nh !Accumulate power spectrum
|
||||
|
128
spec2d.f
128
spec2d.f
@ -1,128 +0,0 @@
|
||||
subroutine spec2d(data,jz,nstep,s2,nchan,nz,psavg0,sigma)
|
||||
|
||||
C Computes 2d spectrogram for FSK441 single-tone search and waterfall
|
||||
C display.
|
||||
|
||||
parameter (NFFT=256)
|
||||
parameter (NR=NFFT+2)
|
||||
parameter (NH=NFFT/2)
|
||||
parameter (NQ=NFFT/4)
|
||||
|
||||
real data(jz)
|
||||
real s2(nchan,nz)
|
||||
real x(NR)
|
||||
real w1(7),w2(7)
|
||||
real psavg(128)
|
||||
real psavg0(128)
|
||||
real ps2(128)
|
||||
complex c(0:NH)
|
||||
common/acom/a1,a2,a3,a4
|
||||
common/fcom/s(3100),indx(3100)
|
||||
equivalence (x,c)
|
||||
save
|
||||
|
||||
df=11025.0/NFFT
|
||||
|
||||
C Compute the 2d spectrogram s2(nchan,nz). Note that in s2 the frequency
|
||||
C bins are shifted down 5 bins from their natural positions.
|
||||
|
||||
call set(0.0,psavg,NH)
|
||||
do n=1,nz
|
||||
j=1 + (n-1)*nstep
|
||||
call move(data(j),x,NFFT)
|
||||
call xfft(x,NFFT)
|
||||
|
||||
sum=0.
|
||||
do i=1,NQ
|
||||
s2(i,n)=real(c(5+i))**2 + aimag(c(5+i))**2
|
||||
sum=sum+s2(i,n)
|
||||
enddo
|
||||
s(n)=sum/NQ
|
||||
|
||||
C Accumulate average spectrum for the whole file.
|
||||
do i=1,nh
|
||||
psavg0(i) = psavg0(i)+ real(c(i))**2 + aimag(c(i))**2
|
||||
enddo
|
||||
enddo
|
||||
|
||||
C Normalize and save a copy of psavg0 for plotting. Roll off the
|
||||
C spectrum at 300 and 3000 Hz.
|
||||
do i=1,nh
|
||||
psavg0(i)=3.e-5*psavg0(i)/nz
|
||||
f=df*i
|
||||
fac=1.0
|
||||
if(f.lt.300.0) fac=f/300.0
|
||||
if(f.gt.3000.0) fac=max(0.00333,(3300.0-f)/300.0)
|
||||
psavg0(i)=(fac**2)*psavg0(i)
|
||||
enddo
|
||||
|
||||
C Compute an average spectrum from the weakest 25% of time slices.
|
||||
call indexx(nz,s,indx)
|
||||
call zero(ps2,NQ)
|
||||
do j=1,nz/4
|
||||
k=indx(j)
|
||||
do i=1,NQ
|
||||
ps2(i+5)=ps2(i+5)+s2(i,k)
|
||||
enddo
|
||||
enddo
|
||||
ps2(1)=ps2(5)
|
||||
ps2(2)=ps2(5)
|
||||
ps2(3)=ps2(5)
|
||||
ps2(4)=ps2(5)
|
||||
sum=0.
|
||||
do i=6,59
|
||||
sum=sum+ps2(i)
|
||||
enddo
|
||||
if(sum.eq.0.0) then
|
||||
sigma=-999.
|
||||
go to 999
|
||||
endif
|
||||
|
||||
C Compute a smoothed spectrum without local peaks, and find its max.
|
||||
smaxx=0.
|
||||
do i=4,NQ
|
||||
sum=0.
|
||||
do k=1,7
|
||||
w1(k)=ps2(i+k-4)
|
||||
sum=sum+w1(k)
|
||||
enddo
|
||||
ave=sum/7.0
|
||||
if(i.ge.14 .and. i.le.58) then
|
||||
call pctile(w1,w2,7,50,base)
|
||||
ave=0.25*(w2(1)+w2(2)+w2(3)+w2(4))
|
||||
endif
|
||||
psavg(i)=ave
|
||||
smaxx=max(psavg(i),smaxx)
|
||||
enddo
|
||||
|
||||
C Save scale factors for flattening spectra of pings.
|
||||
a1=1.0
|
||||
a2=psavg(nint(2*441/df))/psavg(nint(3*441/df))
|
||||
a3=psavg(nint(2*441/df))/psavg(nint(4*441/df))
|
||||
a4=psavg(nint(2*441/df))/psavg(nint(5*441/df))
|
||||
afac=4.0/(a1+a2+a3+a4)
|
||||
a1=afac*a1
|
||||
a2=afac*a2
|
||||
a3=afac*a3
|
||||
a4=afac*a4
|
||||
|
||||
C Normalize 2D spectrum by the average based on weakest 25% of time
|
||||
C slices, smoothed, and with local peaks removed.
|
||||
|
||||
do i=1,NQ
|
||||
do j=1,nz
|
||||
s2(i,j)=s2(i,j)/max(psavg(i+5),0.01*smaxx)
|
||||
enddo
|
||||
enddo
|
||||
|
||||
C Find average of active spectral region, over the whole file.
|
||||
sum=0.
|
||||
do i=9,52
|
||||
do j=1,nz
|
||||
sum=sum+s2(i,j)
|
||||
enddo
|
||||
enddo
|
||||
sigma=sum/(44*nz)
|
||||
|
||||
999 return
|
||||
end
|
37
spec441.f
37
spec441.f
@ -1,37 +0,0 @@
|
||||
subroutine spec441(dat,jz,s,f0)
|
||||
|
||||
C Computes average spectrum over a range of dat, e.g. for a ping.
|
||||
C Returns spectral array and frequency of peak value.
|
||||
|
||||
parameter (NFFT=256)
|
||||
parameter (NR=NFFT+2)
|
||||
parameter (NH=NFFT/2)
|
||||
real*4 dat(jz)
|
||||
real*4 x(NR),s(NH)
|
||||
complex c(0:NH)
|
||||
equivalence (x,c)
|
||||
|
||||
call zero(s,NH)
|
||||
nz=jz/NFFT
|
||||
do n=1,nz
|
||||
j=1 + (n-1)*NFFT
|
||||
call move(dat(j),x,NFFT)
|
||||
call xfft(x,NFFT)
|
||||
do i=1,NH
|
||||
s(i)=s(i)+real(c(i))**2 + aimag(c(i))**2
|
||||
enddo
|
||||
enddo
|
||||
|
||||
smax=0.
|
||||
df=11025.0/NFFT
|
||||
fac=1.0/(100.0*nfft*nz)
|
||||
do i=1,nh
|
||||
s(i)=fac*s(i)
|
||||
if(s(i).gt.smax) then
|
||||
smax=s(i)
|
||||
f0=i*df
|
||||
endif
|
||||
enddo
|
||||
|
||||
return
|
||||
end
|
56
syncf0.f
56
syncf0.f
@ -1,56 +0,0 @@
|
||||
subroutine syncf0(data,jz,NFreeze,NTol,jstart,f0,smax)
|
||||
|
||||
C Does 512-pt FFTs of data with 256-pt step size.
|
||||
C Finds sync tone and determines aproximate values for jstart and f0.
|
||||
|
||||
real data(jz) !Raw data
|
||||
real s2(128,6) !Average spectra at half-symbol spacings
|
||||
real x(512)
|
||||
complex cx(0:511)
|
||||
complex z
|
||||
equivalence (x,cx)
|
||||
|
||||
ps(z)=real(z)**2 + aimag(z)**2 !Power spectrum function
|
||||
|
||||
call zero(s2,6*128) !Clear average
|
||||
df=11025./512.
|
||||
|
||||
ia=(f0-400)/df
|
||||
ib=(f0+400)/df + 0.999
|
||||
if(NFreeze.eq.1) then
|
||||
ia=(f0-NTol)/df
|
||||
ib=(f0+Ntol)/df + 0.999
|
||||
endif
|
||||
|
||||
C Most of the time in this routine is in this loop.
|
||||
|
||||
nblk=jz/256 - 6
|
||||
do n=1,nblk !Accumulate avg spectrum for
|
||||
j=256*(n-1)+1 !512-pt blocks, stepping by 256
|
||||
call move(data(j),x,512)
|
||||
call xfft(x,512)
|
||||
do i=ia,ib
|
||||
x(i)=ps(cx(i))
|
||||
enddo
|
||||
k=mod(n-1,6)+1
|
||||
call add(s2(ia,k),x(ia),s2(ia,k),ib-ia+1) !Average at each step
|
||||
enddo
|
||||
|
||||
C Look for best spectral peak, using the "sync off" phases as reference.
|
||||
smax=0.
|
||||
do i=ia,ib
|
||||
do k=1,6
|
||||
k1=mod(k+1,6)+1
|
||||
k2=mod(k+3,6)+1
|
||||
r=0.5*(s2(i,k1)+s2(i,k2))
|
||||
s=s2(i,k)/r
|
||||
if(s.gt.smax) then
|
||||
smax=s
|
||||
jstart=(k-1)*256 + 1 !Best starting place for sync
|
||||
f0=i*df !Best sync frequency
|
||||
endif
|
||||
enddo
|
||||
enddo
|
||||
|
||||
return
|
||||
end
|
117
syncf1.f
117
syncf1.f
@ -1,117 +0,0 @@
|
||||
subroutine syncf1(data,jz,jstart,f0,NFreeze,DFTolerance,smax,red)
|
||||
|
||||
C Does 16k FFTs of data with stepsize 15360, using only "sync on" intervals.
|
||||
C Returns a refined value of f0, the sync-tone frequency.
|
||||
|
||||
parameter (NFFT=16384)
|
||||
parameter (NH=NFFT/2)
|
||||
parameter (NQ=NFFT/4)
|
||||
parameter (NB3=3*512)
|
||||
real data(jz) !Raw data
|
||||
integer DFTolerance
|
||||
real x(NFFT)
|
||||
real red(512)
|
||||
real s(NQ) !Ref spectrum for flattening and birdie-zapping
|
||||
|
||||
complex c(0:NH)
|
||||
complex z
|
||||
equivalence (x,c)
|
||||
|
||||
ps(z)=real(z)**2 + aimag(z)**2 !Power spectrum ASF
|
||||
|
||||
C Accumulate a high-resolution average spectrum
|
||||
df=11025.0/NFFT
|
||||
jstep=10*NB3
|
||||
nz=(jz-jstart)/jstep -1
|
||||
call zero(s,NQ)
|
||||
do n=1,nz
|
||||
call zero(x,NFFT)
|
||||
k=(n-1)*jstep
|
||||
do i=1,10
|
||||
j=(i-1)*NB3 + 1
|
||||
call move(data(jstart+k+j),x(j),512)
|
||||
enddo
|
||||
call xfft(x,NFFT)
|
||||
do i=1,NQ
|
||||
x(i)=ps(c(i))
|
||||
enddo
|
||||
call add(s,x,s,NQ)
|
||||
enddo
|
||||
|
||||
fac=(1.0/NFFT)**2
|
||||
do i=1,NQ !Normalize
|
||||
s(i)=fac*s(i)
|
||||
enddo
|
||||
call smooth(s,NQ)
|
||||
|
||||
C NB: could also compute a "blue" spectrum, using the sync-off intervals.
|
||||
n8=NQ/8
|
||||
do i=1,n8
|
||||
red(i)=0.
|
||||
do k=8*i-7,8*i
|
||||
red(i)=red(i)+s(k)
|
||||
enddo
|
||||
red(i)=10.0*red(i)/(8.0*nz)
|
||||
enddo
|
||||
|
||||
|
||||
dftol=min(DFTolerance,25)
|
||||
if(nfreeze.eq.1) dftol=DFTolerance
|
||||
C Find improved value for f0
|
||||
smax=0.
|
||||
ia=(f0-dftol)/df
|
||||
ib=(f0+dftol)/df + 0.999
|
||||
! if(NFreeze.eq.1) then
|
||||
! ia=(f0-5.)/df
|
||||
! ib=(f0+5.)/df
|
||||
! endif
|
||||
do i=ia,ib
|
||||
if(s(i).gt.smax) then
|
||||
smax=s(i)
|
||||
ipk=i
|
||||
endif
|
||||
enddo
|
||||
f0=ipk*df
|
||||
|
||||
C Remove line at f0 from spectrum -- if it's strong enough.
|
||||
ia=(f0-150)/df
|
||||
ib=(f0+150)/df
|
||||
a1=0.
|
||||
a2=0.
|
||||
nsum=50
|
||||
do i=1,nsum
|
||||
a1=a1+s(ia-i)
|
||||
a2=a2+s(ib+i)
|
||||
enddo
|
||||
a1=a1/nsum
|
||||
a2=a2/nsum
|
||||
smax=2.0*smax/(a1+a2)
|
||||
|
||||
if(smax.gt.3.0) then
|
||||
b=(a2-a1)/(ib-ia)
|
||||
do i=ia,ib
|
||||
s(i)=a1 + (i-ia)*b
|
||||
enddo
|
||||
endif
|
||||
|
||||
C Make a smoothed version of the spectrum.
|
||||
nsum=50
|
||||
fac=1./(2*nsum+1)
|
||||
call zero(x,nsum)
|
||||
call zero(s,50)
|
||||
call zero(s(NQ-nsum),nsum)
|
||||
sum=0.
|
||||
do i=nsum+1,NQ-nsum
|
||||
sum=sum+s(i+nsum)-s(i-nsum)
|
||||
x(i)=fac*sum
|
||||
enddo
|
||||
call zero(x(NQ-nsum),nsum+1)
|
||||
|
||||
C To zap birdies, compare s(i) and x(i). If s(i) is larger by more
|
||||
C than some limit, replace x(i) by s(i). That will put narrow birdies
|
||||
C on top of the smoothed spectrum.
|
||||
|
||||
call move(x,s,NQ) !Copy smoothed spectrum into s
|
||||
|
||||
return
|
||||
end
|
69
synct.f
69
synct.f
@ -1,69 +0,0 @@
|
||||
subroutine synct(data,jz,jstart,f0,smax)
|
||||
|
||||
C Gets a refined value of jstart.
|
||||
|
||||
parameter (NMAX=30*11025)
|
||||
parameter (NB3=3*512)
|
||||
real data(jz)
|
||||
real*8 dpha,twopi
|
||||
complex*16 z,dz
|
||||
complex c,c1,zz
|
||||
common/hcom/c(NMAX)
|
||||
|
||||
ps(zz)=real(zz)**2 + aimag(zz)**2 !Power spectrum function
|
||||
|
||||
C Convert data to baseband (complex result) using quadrature LO.
|
||||
twopi=8*atan(1.d0)
|
||||
dpha=twopi*f0/11025.d0
|
||||
dz=cmplx(cos(dpha),-sin(dpha))
|
||||
z=1.d0/dz
|
||||
do i=1,jz
|
||||
z=z*dz
|
||||
c(i)=data(i)*z
|
||||
enddo
|
||||
|
||||
C Detect zero-beat sync tone in 512-sample chunks, stepped by 1.
|
||||
C Sums replace original values in c(i).
|
||||
|
||||
zz=0
|
||||
do i=1,512 !Compute first sum
|
||||
zz=zz+c(i)
|
||||
enddo
|
||||
c1=c(1)
|
||||
c(1)=zz
|
||||
do i=2,jz-512 !Compute the rest recursively
|
||||
zz=c(i-1)+c(i+511)-c1
|
||||
c1=c(i) !Save original value
|
||||
c(i)=zz !Save the sum
|
||||
enddo
|
||||
|
||||
C Iterate to find the best jstart.
|
||||
jstart=jstart+NB3
|
||||
nz=(jz-jstart)/NB3 -1
|
||||
smax=0.
|
||||
jstep=256
|
||||
jbest=jstart
|
||||
|
||||
10 jstep=jstep/2
|
||||
jstart=jbest
|
||||
do j=jstart-jstep,jstart+jstep,jstep
|
||||
s=0.
|
||||
r=0.
|
||||
do n=1,nz
|
||||
k=(n-1)*NB3 + j
|
||||
s=s + ps(c(k))
|
||||
r=r + ps(c(k+512)) + ps(c(k+1024))
|
||||
enddo
|
||||
s=2*s/r !Better to use s/r or s-r?
|
||||
if(s.gt.smax) then
|
||||
smax=s
|
||||
jbest=j
|
||||
endif
|
||||
enddo
|
||||
if(jstep.gt.1) go to 10
|
||||
|
||||
jstart=jbest
|
||||
if(jstart.gt.NB3) jstart=jstart-NB3
|
||||
|
||||
return
|
||||
end
|
110
wsjt1.F
110
wsjt1.F
@ -197,116 +197,6 @@ C Intentionally degrade SNR by -nclip dB.
|
||||
goto 900
|
||||
endif
|
||||
|
||||
! If we're in JT6M mode, call the 6M decoding routines.
|
||||
if(mode.eq.4) then
|
||||
do i=1,jz !### Why is it level-sensitive?
|
||||
dat(i)=dat(i)/25.0
|
||||
enddo
|
||||
! For waterfall plot
|
||||
call spec2d(dat,jz,nstep,s2,nchan,nz,psavg,sigma)
|
||||
if(sigma.lt.0.0) basevb=-99.0
|
||||
if(jz/11025.0.lt.3.9 .or. sigma.lt.0.0) go to 900
|
||||
|
||||
f0=1076.66
|
||||
if(NFreeze.eq.1) f0=1076.66 + MouseDF
|
||||
f00=f0
|
||||
call syncf0(dat,jz,NFreeze,DFTolerance,jstart,f0,smax)
|
||||
call synct(dat,jz,jstart,f0,smax)
|
||||
call syncf1(dat,jz,jstart,f0,NFreeze,DFTolerance,smax,red)
|
||||
|
||||
do i=1,512
|
||||
ccf(i-6)=dB(red(i))
|
||||
enddo
|
||||
df=11025./256.
|
||||
do i=1,64
|
||||
sum=0.
|
||||
do k=8*i-7,8*i
|
||||
sum=sum+red(k)
|
||||
enddo
|
||||
psavg(i)=5.0*sum
|
||||
fac=1.0
|
||||
freq=i*df
|
||||
if(freq.gt.2500.0) fac=((freq-2500.)/20.0)**(-1.0)
|
||||
psavg(i)=fac*psavg(i)
|
||||
psavg(i+64)=0.001
|
||||
enddo
|
||||
|
||||
jz=jz-jstart+1
|
||||
nslim=MinSigdB
|
||||
NFixLen=0
|
||||
|
||||
C Call the decoder if DF is in range or Freeze is off.
|
||||
if(NFreeze.eq.0 .or.
|
||||
+ abs(f0-f00).lt.float(DFTolerance)) then
|
||||
call decode6m(dat(jstart),jz,cfile6,nslim,istart,
|
||||
+ NFixLen,lcum,f0,lumsg,npkept,yellow)
|
||||
endif
|
||||
|
||||
if(pick) then
|
||||
do i=1,216
|
||||
ps0(i)=yellow0(i)
|
||||
enddo
|
||||
else
|
||||
ps0(216)=yellow(216)
|
||||
yellow0(216)=yellow(216)
|
||||
do i=1,215
|
||||
ps0(i)=2*yellow(i)
|
||||
yellow0(i)=ps0(i)
|
||||
enddo
|
||||
endif
|
||||
goto 800
|
||||
endif
|
||||
|
||||
! We're in FSK441 mode. Compute the 2D spectrum.
|
||||
df=11025.0/256.0 !FFT resolution ~43 Hz
|
||||
dtbuf=nstep/11025.0
|
||||
stlim=nslim2 !Single-tone threshold
|
||||
call spec2d(dat,jz,nstep,s2,nchan,nz,psavg,sigma)
|
||||
if(sigma.lt.0.0) basevb=-99.0
|
||||
if(sigma.lt.0.0) go to 900
|
||||
nline0=nline
|
||||
STfound=.false.
|
||||
npkept=0
|
||||
|
||||
C Look for single-tone messages
|
||||
if((.not.pick) .or. MouseButton.eq.1) then
|
||||
call stdecode(s2,nchan,nz,sigma,dtbuf,df,stlim,
|
||||
+ DFTolerance,cfile6,pick,istart)
|
||||
endif
|
||||
if(nline.gt.nline0) STfound=.true. !ST message(s) found
|
||||
|
||||
C Now the multi-tone decoding
|
||||
call mtdecode(dat,jz,nz,MinSigdB,MinWidth,
|
||||
+ NQRN,DFTolerance,istart,pick,cfile6,ps0)
|
||||
|
||||
npkept=nline !Number of pings that were kept
|
||||
smax=0.
|
||||
stbest=.false.
|
||||
if(npkept.gt.0) then
|
||||
call indexx(npkept,tping,indx) !Merge the ST and MT decodes
|
||||
do i=1,npkept
|
||||
j=indx(i)
|
||||
if(pick .and. STFound .and.
|
||||
+ line(j)(29:31).eq.' ') goto 10
|
||||
write(lumsg,1050) line(j) !Write to decoded.txt
|
||||
1050 format(a79)
|
||||
if(lcum) write(21,1050) line(j) !Write to ALL.TXT
|
||||
read(line(j),1060) sig,msg3
|
||||
1060 format(16x,f3.0,9x,a3)
|
||||
if(sig.gt.smax) then
|
||||
smax=sig
|
||||
tbest=tping(j)
|
||||
stbest = (msg3.ne.' ')
|
||||
endif
|
||||
10 enddo
|
||||
endif
|
||||
|
||||
dt=1.0/11025.0 !Compute spectrum for pink curve
|
||||
if(stbest) then
|
||||
jj=nint(tbest/dt)
|
||||
call spec441(dat(jj),1102,ps0,f0)
|
||||
endif
|
||||
|
||||
800 continue
|
||||
call s2shape(s2,nchan,nz,tbest)
|
||||
|
||||
|
123
wsjtgen.F90
123
wsjtgen.F90
@ -117,121 +117,34 @@ subroutine wsjtgen
|
||||
dt=1.d0/fsample_out
|
||||
LTone=2
|
||||
|
||||
if(mode(1:4).eq.'JT65') then
|
||||
! We're in JT65 mode.
|
||||
if(mode(5:5).eq.'A') mode65=1
|
||||
if(mode(5:5).eq.'B') mode65=2
|
||||
if(mode(5:5).eq.'C') mode65=4
|
||||
call gen65(msg,mode65,samfacout,iwave,nwave,sendingsh,msgsent)
|
||||
if(mode(5:5).eq.'A') mode65=1
|
||||
if(mode(5:5).eq.'B') mode65=2
|
||||
if(mode(5:5).eq.'C') mode65=4
|
||||
call gen65(msg,mode65,samfacout,iwave,nwave,sendingsh,msgsent)
|
||||
|
||||
if(lcwid) then
|
||||
! Generate and insert the CW ID.
|
||||
wpm=25.
|
||||
freqcw=800.
|
||||
idmsg=MyCall//' '
|
||||
call gencwid(idmsg,wpm,freqcw,samfacout,icwid,ncwid)
|
||||
k=nwave
|
||||
do i=1,ncwid
|
||||
k=k+1
|
||||
iwave(k)=icwid(i)
|
||||
enddo
|
||||
do i=1,2205 !Add 0.2 s of silence
|
||||
k=k+1
|
||||
iwave(k)=0
|
||||
enddo
|
||||
nwave=k
|
||||
endif
|
||||
|
||||
goto 900
|
||||
endif
|
||||
|
||||
if(mode(1:4).eq.'Echo') then
|
||||
! We're in Echo mode.
|
||||
! dither=AmpA
|
||||
! call echogen(dither,wavefile,nbytes,f1)
|
||||
! AmpB=f1
|
||||
goto 900
|
||||
endif
|
||||
|
||||
if(mode(1:4).eq.'JT6M') then
|
||||
! We're in JT6M mode.
|
||||
call gen6m(msg,samfacout,iwave,nwave)
|
||||
goto 900
|
||||
endif
|
||||
|
||||
if(mode(1:2).eq.'CW') then
|
||||
! We're in CW mode
|
||||
wpm=15.
|
||||
freqcw=800.
|
||||
call gencw(msg,wpm,freqcw,samfacout,TRPeriod,iwave,nwave)
|
||||
goto 900
|
||||
endif
|
||||
|
||||
! We're in FSK441 mode.
|
||||
if(nmsg.lt.28) nmsg=nmsg+1 !Add trailing blank if nmsg < 28
|
||||
|
||||
! Check for shorthand messages
|
||||
sendingsh = 0
|
||||
if(shok.eq.1 .and. nmsg.le.4) then
|
||||
if (msg(1:3).eq.'R26') then
|
||||
msg='++'
|
||||
nmsg=2
|
||||
sendingsh = 1
|
||||
else if (msg(1:3).eq.'R27') then
|
||||
msg='**'
|
||||
nmsg=2
|
||||
sendingsh = 1
|
||||
else if (msg(1:3).eq.'RRR') then
|
||||
msg='%%'
|
||||
nmsg=2
|
||||
sendingsh = 1
|
||||
else if (msg(1:2).eq.'73') then
|
||||
msg='@@'
|
||||
nmsg=2
|
||||
sendingsh = 1
|
||||
endif
|
||||
endif
|
||||
|
||||
! Encode the message
|
||||
call abc441(msg,nmsg,itone,ndits)
|
||||
ndata=ndits*nspd
|
||||
|
||||
! Generate iwave
|
||||
k=0
|
||||
df=11025.0/NSPD
|
||||
do m=1,ndits
|
||||
freq=(LTone-1+itone(m))*df
|
||||
dpha=twopi*freq*dt
|
||||
do i=1,NSPD
|
||||
k=k+1
|
||||
pha=pha+dpha
|
||||
iwave(k)=nint(32767.0*sin(pha))
|
||||
enddo
|
||||
enddo
|
||||
nwave=k
|
||||
|
||||
900 sending=txmsg
|
||||
if(mode(1:4).eq.'JT65' .and. sendingsh.ne.1) sending=msgsent
|
||||
nmsg=nmsg0
|
||||
|
||||
if(lcwid .and. (mode.eq.'FSK441' .or. mode(1:4).eq.'JT6M')) then
|
||||
if(lcwid) then
|
||||
! Generate and insert the CW ID.
|
||||
wpm=25.
|
||||
freqcw=440.
|
||||
freqcw=800.
|
||||
idmsg=MyCall//' '
|
||||
call gencwid(idmsg,wpm,freqcw,samfacout,icwid,ncwid)
|
||||
k=0
|
||||
do i=ncwid+1,int(trperiod*fsample_out)
|
||||
k=k+1
|
||||
if(k.gt.nwave) k=k-nwave
|
||||
iwave(i)=iwave(k)
|
||||
enddo
|
||||
k=nwave
|
||||
do i=1,ncwid
|
||||
iwave(i)=icwid(i)
|
||||
k=k+1
|
||||
iwave(k)=icwid(i)
|
||||
enddo
|
||||
nwave=trperiod*fsample_out
|
||||
do i=1,2205 !Add 0.2 s of silence
|
||||
k=k+1
|
||||
iwave(k)=0
|
||||
enddo
|
||||
nwave=k
|
||||
endif
|
||||
|
||||
900 sending=txmsg
|
||||
if(sendingsh.ne.1) sending=msgsent
|
||||
nmsg=nmsg0
|
||||
|
||||
999 return
|
||||
end subroutine wsjtgen
|
||||
|
||||
|
Loading…
Reference in New Issue
Block a user