WSJT-X/lib/fst280/fst280d.f90

478 lines
13 KiB
Fortran

program fst280d
! Decode fst280 data read from *.c2 or *.wav files.
use packjt77
include 'fst280_params.f90'
character arg*8,infile*80,fname*16,datetime*11
! character ch1*1,ch4*4,cseq*31
! character*22 decodes(100)
character*37 msg
character*120 data_dir
character*77 c77
character*1 tr_designator
complex, allocatable :: c2(:)
complex, allocatable :: cframe(:)
complex, allocatable :: c_bigfft(:) !Complex waveform
real, allocatable :: r_data(:)
real*8 fMHz
real llr(280),llra(280),llrb(280),llrc(280),llrd(280)
real candidates(100,3)
real bitmetrics(328,4)
integer ihdr(11)
integer*2, allocatable :: iwave(:)
integer*1 apmask(280),cw(280)
integer*1 hbits(328)
integer*1 message101(101),message74(74)
logical badsync,unpk77_success
hmod=1.0
Keff=91
ndeep=3
iwspr=0
nargs=iargc()
if(nargs.lt.1) then
print*,'Usage: fst280d [-a <data_dir>] [-f fMHz] [-h hmod] [-k Keff] file1 [file2 ...]'
go to 999
endif
iarg=1
data_dir="."
call getarg(iarg,arg)
if(arg(1:2).eq.'-a') then
call getarg(iarg+1,data_dir)
iarg=iarg+2
call getarg(iarg,arg)
endif
if(arg(1:2).eq.'-f') then
call getarg(iarg+1,arg)
read(arg,*) fMHz
iarg=iarg+2
call getarg(iarg,arg)
endif
if(arg(1:2).eq.'-h') then
call getarg(iarg+1,arg)
read(arg,*) hmod
if(hmod.ne.1.and.hmod.ne.2.and.hmod.ne.4) then
print*,'invalid modulation index. h must be 1, 2, or 4'
goto 999
endif
iarg=iarg+2
call getarg(iarg,arg)
endif
if(arg(1:2).eq.'-k') then
call getarg(iarg+1,arg)
read(arg,*) Keff
if(Keff.le.74) iwspr=1
iarg=iarg+2
call getarg(iarg,arg)
endif
if(arg(1:2).eq.'-d') then
call getarg(iarg+1,arg)
read(arg,*) ndeep
iarg=iarg+2
call getarg(iarg,arg)
endif
if(arg(1:2).eq.'-t') then
call getarg(iarg+1,arg)
read(arg,*) tr_designator
iarg=iarg+2
endif
nmax=15*12000
select case (tr_designator)
case('A')
nsps=800
nmax=15*12000
ndown=32/hmod
case('B')
nsps=1680
nmax=30*12000
ndown=70/hmod
if(hmod.eq.4) ndown=15
case('C')
nsps=4000
nmax=60*12000
ndown=160/hmod
case('D')
nsps=8400
nmax=120*12000
ndown=350/hmod
if(hmod.eq.4) ndown=84
case('E')
nsps=21504
nmax=300*12000
ndown=896/hmod
end select
nss=nsps/ndown
fs=12000.0 !Sample rate
fs2=fs/ndown
nspsec=nint(fs2)
dt=1.0/fs !Sample interval (s)
dt2=1.0/fs2
tt=nsps*dt !Duration of "itone" symbols (s)
nfft1=2*int(nmax/2)
nh1=nfft1/2
allocate( r_data(1:nfft1+2) )
allocate( c_bigfft(0:nfft1/2) )
nfft2=nfft1/ndown
allocate( c2(0:nfft2-1) )
allocate( cframe(0:164*nss-1) )
allocate( iwave(nmax) )
!write(*,*) 'nsps: ',nsps
!write(*,*) 'nmax: ',nmax
!write(*,*) 'nss : ',nss
!write(*,*) 'nspsec: ',fs2
!write(*,*) 'nfft1 : ',nfft1
!write(*,*) 'nfft2 : ',nfft2
ngood=0
ngoodsync=0
nfile=0
do ifile=iarg,nargs
nfile=nfile+1
call getarg(ifile,infile)
open(10,file=infile,status='old',access='stream')
j1=index(infile,'.c2')
j2=index(infile,'.wav')
if(j1.gt.0) then
read(10,end=999) fname,ntrmin,fMHz,c2
read(fname(8:11),*) nutc
write(datetime,'(i11)') nutc
else if(j2.gt.0) then
read(10,end=999) ihdr,iwave
read(infile(j2-4:j2-1),*) nutc
datetime=infile(j2-11:j2-1)
else
print*,'Wrong file format?'
go to 999
endif
close(10)
npts=nmax
fa=100.0
fb=3500.0
! The big fft is done once and is used for calculating the smoothed spectrum
! and also for downconverting/downsampling each candidate.
r_data(1:nfft1)=iwave(1:nfft1)
r_data(nfft1+1:nfft1+2)=0.0
call four2a(r_data,nfft1,1,-1,0)
c_bigfft=cmplx(r_data(1:nfft1+2:2),r_data(2:nfft1+2:2))
! Get first approximation of candidate frequencies
call get_candidates_fst280(c_bigfft,nfft1,nsps,hmod,fs,fa,fb,ncand,candidates)
ndecodes=0
isbest1=0
isbest8=0
fc21=fc0
fc28=fc0
do icand=1,ncand
fc0=candidates(icand,1)
xsnr=candidates(icand,2)
! Downconvert and downsample a slice of the spectrum centered on the
! rough estimate of the candidates frequency.
! Output array c2 is complex baseband sampled at 12000/ndown Sa/sec.
! The size of the downsampled c2 array is nfft2=nfft1/ndown
call fst280_downsample(c_bigfft,nfft1,ndown,fc0,c2)
! write(*,3001) c2(nfft2/3),candidates(icand,1:2)
!3001 format(2e15.6,2f10.3)
do isync=0,1
if(isync.eq.0) then
fc1=0.0
is0=nint(fs2)
ishw=is0
isst=4
ifhw=10
df=.1*8400/nsps
else if(isync.eq.1) then
fc1=fc28
is0=isbest8
ishw=4
isst=1
ifhw=10
df=.02*8400/nsps
endif
smax1=0.0
smax8=0.0
do if=-ifhw,ifhw
fc=fc1+df*if
do istart=max(1,is0-ishw),is0+ishw,isst
call sync_fst280(c2,istart,fc,hmod,1,nfft2,nss,fs2,sync1)
call sync_fst280(c2,istart,fc,hmod,8,nfft2,nss,fs2,sync8)
if(sync8.gt.smax8) then
fc28=fc
isbest8=istart
smax8=sync8
endif
if(sync1.gt.smax1) then
fc21=fc
isbest1=istart
smax1=sync1
endif
enddo
enddo
! write(*,1022) ifile,icand,isync,fc1, &
! fc21,isbest1,smax1,fc28,isbest8,smax8
!1022 format(i5,1x,i4,1x,i4,1x,f7.2,1x,2(1x,f7.2,1x,i5,1x,e9.3))
enddo
if(smax8/smax1 .lt. 0.65 ) then
fc2=fc21
isbest=isbest1
ntmax=4
if(hmod .gt. 1.0) ntmax=1
ntmin=1
njitter=2
else
fc2=fc28
isbest=isbest8
ntmax=4
if(hmod .gt. 1.0) ntmax=1
ntmin=1
njitter=2
endif
fc_synced = fc0 + fc2
dt_synced = (isbest-fs2)*dt2 !nominal dt is 1 second so frame starts at sample fs2
call fst280_downsample(c_bigfft,nfft1,ndown,fc_synced,c2)
if(abs((isbest-fs2)/nss) .lt. 0.2 .and. abs(fc_synced-1500.0).lt.0.4) then
ngoodsync=ngoodsync+1
endif
do ijitter=0,2
if(ijitter.eq.0) ioffset=0
if(ijitter.eq.1) ioffset=2
if(ijitter.eq.2) ioffset=-2
is0=isbest+ioffset
if(is0.lt.0) cycle
cframe=c2(is0:is0+164*nss-1)
s2=sum(cframe*conjg(cframe))
cframe=cframe/sqrt(s2)
call get_fst280_bitmetrics(cframe,nss,hmod,bitmetrics,badsync)
hbits=0
where(bitmetrics(:,1).ge.0) hbits=1
ns1=count(hbits( 1: 8).eq.(/0,0,0,1,1,0,1,1/))
ns2=count(hbits( 9: 16).eq.(/0,1,0,0,1,1,1,0/))
ns3=count(hbits(157:164).eq.(/0,0,0,1,1,0,1,1/))
ns4=count(hbits(165:172).eq.(/0,1,0,0,1,1,1,0/))
ns5=count(hbits(313:320).eq.(/0,0,0,1,1,0,1,1/))
ns6=count(hbits(321:328).eq.(/0,1,0,0,1,1,1,0/))
nsync_qual=ns1+ns2+ns3+ns4+ns5+ns6
! if(nsync_qual.lt. 20) cycle
scalefac=2.83
llra( 1:140)=bitmetrics( 17:156, 1)
llra(141:280)=bitmetrics(173:312, 1)
llra=scalefac*llra
llrb( 1:140)=bitmetrics( 17:156, 2)
llrb(141:280)=bitmetrics(173:312, 2)
llrb=scalefac*llrb
llrc( 1:140)=bitmetrics( 17:156, 3)
llrc(141:280)=bitmetrics(173:312, 3)
llrc=scalefac*llrc
llrd( 1:140)=bitmetrics( 17:156, 4)
llrd(141:280)=bitmetrics(173:312, 4)
llrd=scalefac*llrd
apmask=0
do itry=ntmax,ntmin,-1
if(itry.eq.1) llr=llra
if(itry.eq.2) llr=llrb
if(itry.eq.3) llr=llrc
if(itry.eq.4) llr=llrd
dmin=0.0
nharderrors=-1
unpk77_success=.false.
if(iwspr.eq.0) then
maxosd=2
call decode280_101(llr,Keff,maxosd,ndeep,apmask,message101,cw,ntype,nharderrors,dmin)
else
maxosd=2
call decode280_74(llr,Keff,maxosd,ndeep,apmask,message74,cw,ntype,nharderrors,dmin)
endif
if(nharderrors .ge.0) then
if(iwspr.eq.0) then
write(c77,'(77i1)') message101(1:77)
call unpack77(c77,0,msg,unpk77_success)
else
write(c77,'(50i1)') message74(1:50)
c77(51:77)='000000000000000000000110000'
call unpack77(c77,0,msg,unpk77_success)
endif
if(nharderrors .ge.0 .and. unpk77_success) then
ngood=ngood+1
write(*,1100) nfile,icand,xsnr,dt_synced,fc_synced, &
itry,ntype,nharderrors,dmin,ijitter,nsync_qual,msg(1:22)
1100 format(i5,i5,f6.1,f6.2,f7.1,i4,i4,i4,f7.2,i6,i6,2x,a22)
goto 2002
else
cycle
endif
endif
enddo ! metrics
enddo ! istart jitter
2002 continue
enddo !candidate list
enddo !files
nfiles=nargs-iarg+1
write(*,*) 'nfiles: ',nfiles,' ngood: ',ngood,' ngoodsync: ',ngoodsync
write(*,1120)
1120 format("<DecodeFinished>")
999 end program fst280d
subroutine sync_fst280(cd0,i0,f0,hmod,ncoh,np,nss,fs,sync)
! Compute sync power for a complex, downsampled FST280 signal.
include 'fst280_params.f90'
complex cd0(0:np-1)
complex, allocatable, save :: csync(:)
complex, allocatable, save :: csynct(:)
complex ctwk(8*nss)
complex z1,z2,z3
logical first
integer isyncword(0:7)
real f0save
data isyncword/0,1,3,2,1,0,2,3/
data first/.true./
data f0save/0.0/
save first,twopi,dt,fac,f0save
p(z1)=(real(z1*fac)**2 + aimag(z1*fac)**2)**0.5 !Statement function for power
if( first ) then
allocate( csync(8*nss) )
allocate( csynct(8*nss) )
twopi=8.0*atan(1.0)
dt=1/fs
k=1
phi=0.0
do i=0,7
dphi=twopi*hmod*(isyncword(i)-1.5)/real(nss)
do j=1,nss
csync(k)=cmplx(cos(phi),sin(phi))
phi=mod(phi+dphi,twopi)
k=k+1
enddo
enddo
first=.false.
fac=1.0/(8.0*nss)
endif
if(f0.ne.f0save) then
dphi=twopi*f0*dt
phi=0.0
do i=1,8*nss
ctwk(i)=cmplx(cos(phi),sin(phi))
phi=mod(phi+dphi,twopi)
enddo
csynct=ctwk*csync
f0save=f0
endif
i1=i0 !Costas arrays
i2=i0+78*nss
i3=i0+156*nss
s1=0.0
s2=0.0
s3=0.0
nsec=8/ncoh
do i=1,nsec
is=(i-1)*ncoh*nss
z1=sum(cd0(i1+is:i1+is+ncoh*nss-1)*conjg(csynct(is+1:is+ncoh*nss)))
z2=sum(cd0(i2+is:i2+is+ncoh*nss-1)*conjg(csynct(is+1:is+ncoh*nss)))
z3=sum(cd0(i3+is:i3+is+ncoh*nss-1)*conjg(csynct(is+1:is+ncoh*nss)))
s1=s1+abs(z1)/(8*nss)
s2=s2+abs(z2)/(8*nss)
s3=s3+abs(z3)/(8*nss)
enddo
sync = s1+s2+s3
return
end subroutine sync_fst280
subroutine fst280_downsample(c_bigfft,nfft1,ndown,f0,c1)
! Output: Complex data in c(), sampled at 12000/ndown Hz
complex c_bigfft(0:nfft1/2)
complex c1(0:nfft1/ndown-1)
df=12000.0/nfft1
i0=nint(f0/df)
c1(0)=c_bigfft(i0)
nfft2=nfft1/ndown
do i=1,nfft2/2
if(i0+i.le.nfft1/2) c1(i)=c_bigfft(i0+i)
if(i0-i.ge.0) c1(nfft2-i)=c_bigfft(i0-i)
enddo
c1=c1/nfft2
call four2a(c1,nfft2,1,1,1) !c2c FFT back to time domain
return
end subroutine fst280_downsample
subroutine get_candidates_fst280(c_bigfft,nfft1,nsps,hmod,fs,fa,fb,ncand,candidates)
complex c_bigfft(0:nfft1/2)
real candidates(100,3)
real s(18000)
real s2(18000)
data nfft1z/-1/
save nfft1z
nh1=nfft1/2
df1=fs/nfft1
baud=fs/nsps
df2=baud/2.0
nd=df1/df2
ndh=nd/2
ia=fa/df2
ib=fb/df2
s=0.
do i=ia,ib
j0=nint(i*df2/df1)
do j=j0-ndh,j0+ndh
s(i)=s(i) + real(c_bigfft(j))**2 + aimag(c_bigfft(j))**2
enddo
enddo
call pctile(s(ia:ib),ib-ia+1,30,base)
s=s/base
nh=hmod
do i=ia,ib
s2(i)=s(i-nh*3) + s(i-nh) +s(i+nh) +s(i+nh*3)
s2(i)=db(s2(i)) - 48.5
enddo
if(nh.eq.1) thresh=-29.5
if(nh.eq.2) thresh=-27.0
if(nh.eq.4) thresh=-25.0
ncand=0
do i=ia,ib
if((s2(i).gt.s2(i-1)).and. &
(s2(i).gt.s2(i+1)).and. &
(s2(i).gt.thresh).and.ncand.lt.100) then
ncand=ncand+1
candidates(ncand,1)=df2*i
candidates(ncand,2)=s2(i)
endif
enddo
return
end subroutine get_candidates_fst280