ft8d/sync8.f90
2018-04-02 10:37:24 +02:00

154 lines
3.9 KiB
Fortran

subroutine sync8(dd,nfa,nfb,syncmin,nfqso,s,candidate,ncand,sbase)
include 'ft8_params.f90'
! Search over +/- 2.5s relative to 0.5s TX start time.
parameter (JZ=62)
complex cx(NFFT1)
real s(NFFT1,NHSYM)
real savg(NFFT1)
real sbase(NFFT1)
complex x(NFFT1)
real sync2d(NFFT1,-JZ:JZ)
real red(NFFT1)
real candidate0(3,200)
real candidate(3,200)
complex dd(NMAX)
integer jpeak(NFFT1)
integer indx(NFFT1)
integer ii(1)
integer icos7(0:6)
data icos7/2,5,6,0,4,1,3/ !Costas 7x7 tone pattern
equivalence (x,cx)
! Compute symbol spectra, stepping by NSTEP steps.
savg=0.
tstep=NSTEP/4000.0
df=4000.0/NFFT1 !3.125 Hz
fac=1.0/300.0
do j=1,NHSYM
ia=(j-1)*NSTEP + 1
ib=ia+NSPS-1
x(1:NSPS)=fac*dd(ia:ib)
x(NSPS+1:)=0.
call four2a(x,NFFT1,1,-1,1) !c2c FFT
do i=2,NH1
s(i-1,j)=real(cx(i+NH1))**2 + aimag(cx(i+NH1))**2
s(i-1+NH1,j)=real(cx(i))**2 + aimag(cx(i))**2
enddo
s(NH1,j)=real(cx(1))**2 + aimag(cx(1))**2
savg=savg + s(1:NFFT1,j) !Average spectrum
enddo
call baseline(savg,nfa,nfb,sbase)
! savg=savg/NHSYM
! do i=1,NH1
! write(51,3051) i*df,savg(i),db(savg(i))
!3051 format(f10.3,e12.3,f12.3)
! enddo
ia=max(1,nint(nfa/df))
ib=nint(nfb/df)
nssy=NSPS/NSTEP ! # steps per symbol
nfos=NFFT1/NSPS ! # frequency bin oversampling factor
jstrt=0.5/tstep
do i=ia,ib
do j=-JZ,+JZ
ta=0.
tb=0.
tc=0.
t0a=0.
t0b=0.
t0c=0.
do n=0,6
k=j+jstrt+nssy*n
if(k.ge.1.and.k.le.NHSYM) then
ta=ta + s(i+nfos*icos7(n),k)
t0a=t0a + sum(s(i:i+nfos*6:nfos,k))
endif
tb=tb + s(i+nfos*icos7(n),k+nssy*36)
t0b=t0b + sum(s(i:i+nfos*6:nfos,k+nssy*36))
if(k+nssy*72.le.NHSYM) then
tc=tc + s(i+nfos*icos7(n),k+nssy*72)
t0c=t0c + sum(s(i:i+nfos*6:nfos,k+nssy*72))
endif
enddo
t=ta+tb+tc
t0=t0a+t0b+t0c
t0=(t0-t)/6.0
sync_abc=t/t0
t=tb+tc
t0=t0b+t0c
t0=(t0-t)/6.0
sync_bc=t/t0
sync2d(i,j)=max(sync_abc,sync_bc)
enddo
enddo
red=0.
do i=ia,ib
ii=maxloc(sync2d(i,-JZ:JZ)) - 1 - JZ
j0=ii(1)
jpeak(i)=j0
red(i)=sync2d(i,j0)
! write(52,3052) i*df,red(i),db(red(i))
!3052 format(3f12.3)
enddo
iz=ib-ia+1
call indexx(red(ia:ib),iz,indx)
ibase=indx(nint(0.40*iz)) - 1 + ia
base=red(ibase)
red=red/base
candidate0=0.
k=0
do i=1,200
n=ia + indx(iz+1-i) - 1
if(red(n).lt.syncmin) exit
if(k.lt.200) k=k+1
candidate0(1,k)=n*df
candidate0(2,k)=(jpeak(n)-1)*tstep
candidate0(3,k)=red(n)
enddo
ncand=k
! Put nfqso at top of list, and save only the best of near-dupe freqs.
do i=1,ncand
if(abs(candidate0(1,i)-nfqso).lt.10.0) candidate0(1,i)=-candidate0(1,i)
if(i.ge.2) then
do j=1,i-1
fdiff=abs(candidate0(1,i))-abs(candidate0(1,j))
if(abs(fdiff).lt.4.0) then
if(candidate0(3,i).ge.candidate0(3,j)) candidate0(3,j)=0.
if(candidate0(3,i).lt.candidate0(3,j)) candidate0(3,i)=0.
endif
enddo
! write(*,3001) i,candidate0(1,i-1),candidate0(1,i),candidate0(3,i-1), &
! candidate0(3,i)
!3001 format(i2,4f8.1)
endif
enddo
fac=20.0/maxval(s)
s=fac*s
! Sort by sync
! call indexx(candidate0(3,1:ncand),ncand,indx)
! Sort by frequency
call indexx(candidate0(1,1:ncand),ncand,indx)
k=1
! do i=ncand,1,-1
do i=1,ncand
j=indx(i)
! if( candidate0(3,j) .ge. syncmin .and. candidate0(2,j).ge.-1.5 ) then
if( candidate0(3,j) .ge. syncmin ) then
candidate(1,k)=abs(candidate0(1,j))
candidate(2,k)=candidate0(2,j)
candidate(3,k)=candidate0(3,j)
k=k+1
endif
enddo
ncand=k-1
return
end subroutine sync8