module wideband_sync type candidate real :: snr !Relative S/N of sync detection real :: f !Freq of sync tone, 0 to 96000 Hz real :: xdt !DT of matching sync pattern, -1.0 to +4.0 s real :: pol !Polarization angle, degrees integer :: ipol !Polarization angle, 1 to 4 ==> 0, 45, 90, 135 deg integer :: iflip !Sync type: JT65 = +/- 1, Q65 = 0 end type candidate type sync_dat real :: ccfmax real :: xdt real :: pol integer :: ipol integer :: iflip logical :: birdie end type sync_dat parameter (NFFT=32768) parameter (MAX_CANDIDATES=50) parameter (SNR1_THRESHOLD=4.5) type(sync_dat) :: sync(NFFT) integer nkhz_center contains subroutine get_candidates(ss,savg,xpol,nfa,nfb,nts_jt65,nts_q65,cand,ncand) ! Search symbol spectra ss() over frequency range nfa to nfb (in kHz) for ! JT65 and Q65 sync patterns. The nts_* variables are the submode tone ! spacings: 1 2 4 8 16 for A B C D E. Birdies are detected and ! excised. Candidates are returned in the structure array cand(). parameter (MAX_PEAKS=300) real ss(4,322,NFFT),savg(4,NFFT) real pavg(-20:20) integer indx(NFFT) logical xpol,skip type(candidate) :: cand(MAX_CANDIDATES) do j=322,1,-1 !Find end of data in ss() if(sum(ss(1,j,1:NFFT)).gt.0.0) exit enddo jz=j call wb_sync(ss,savg,xpol,jz,nfa,nfb) tstep=2048.0/11025.0 !0.185760 s: 0.5*tsym_jt65, 0.3096*tsym_q65 df3=96000.0/NFFT ia=nint(1000*nfa/df3) + 1 ib=nint(1000*nfb/df3) + 1 iz=ib-ia+1 call indexx(sync(ia:ib)%ccfmax,iz,indx) !Sort by relative snr k=0 do i=1,MAX_PEAKS n=indx(iz+1-i) + ia - 1 f0=0.001*(n-1)*df3 snr1=sync(n)%ccfmax ! print*,'=A',f0,snr1 if(snr1.lt.SNR1_THRESHOLD) exit flip=sync(n)%iflip if(flip.ne.0.0 .and. nts_jt65.eq.0) cycle if(flip.eq.0.0 .and. nts_q65.eq.0) cycle if(sync(n)%birdie) cycle ! Test for signal outside of TxT range and set bw for this signal type j1=(sync(n)%xdt + 1.0)/tstep - 1.0 j2=(sync(n)%xdt + 52.0)/tstep + 1.0 if(flip.ne.0) j2=(sync(n)%xdt + 47.811)/tstep + 1.0 ipol=sync(n)%ipol pavg=0. do j=1,j1 pavg=pavg + ss(ipol,j,n-20:n+20) enddo do j=j2,jz pavg=pavg + ss(ipol,j,n-20:n+20) enddo jsum=j1 + (jz-j2+1) pmax=maxval(pavg(-2:2)) !### Why not just pavg(0) ? base=(sum(pavg)-pmax)/jsum pmax=pmax/base if(pmax.gt.5.0) cycle skip=.false. do m=1,k !Skip false syncs within signal bw diffhz=1000.0*(f0-cand(m)%f) bw=nts_q65*110.0 if(cand(m)%iflip.ne.0) bw=nts_jt65*178.0 if(diffhz.gt.-20.0 .and. diffhz.lt.bw+20.0) skip=.true. ! write(*,3301) i,k,m,f0,cand(m)%f,diffhz,snr1,skip !3301 format('=',3i5,f10.1,3f10.3,L3) enddo if(skip) cycle k=k+1 cand(k)%snr=snr1 cand(k)%f=f0 cand(k)%xdt=sync(n)%xdt cand(k)%pol=sync(n)%pol cand(k)%ipol=sync(n)%ipol cand(k)%iflip=nint(flip) if(k.ge.MAX_CANDIDATES) exit enddo ncand=k return end subroutine get_candidates subroutine wb_sync(ss,savg,xpol,jz,nfa,nfb) ! Compute "orange sync curve" using the Q65 sync pattern use timer_module, only: timer parameter (NFFT=32768) parameter (LAGMAX=30) real ss(4,322,NFFT) real savg(4,NFFT) real savg_med(4) real ccf4(4),ccf4best(4),a(3) logical first,xpol integer isync(22) integer jsync0(63),jsync1(63) integer ip(1) ! Q65 sync symbols data isync/1,9,12,13,15,22,23,26,27,33,35,38,46,50,55,60,62,66,69,74,76,85/ data jsync0/ & 1, 4, 5, 9, 10, 11, 12, 13, 14, 16, 18, 22, 24, 25, 28, 32, & 33, 34, 37, 38, 39, 40, 42, 43, 45, 46, 47, 48, 52, 53, 55, 57, & 59, 60, 63, 64, 66, 68, 70, 73, 80, 81, 89, 90, 92, 95, 97, 98, & 100,102,104,107,108,111,114,119,120,121,122,123,124,125,126/ data jsync1/ & 2, 3, 6, 7, 8, 15, 17, 19, 20, 21, 23, 26, 27, 29, 30, 31, & 35, 36, 41, 44, 49, 50, 51, 54, 56, 58, 61, 62, 65, 67, 69, 71, & 72, 74, 75, 76, 77, 78, 79, 82, 83, 84, 85, 86, 87, 88, 91, 93, & 94, 96, 99,101,103,105,106,109,110,112,113,115,116,117,118/ data first/.true./ save first,isync,jsync0,jsync1 tstep=2048.0/11025.0 !0.185760 s: 0.5*tsym_jt65, 0.3096*tsym_q65 if(first) then fac=0.6/tstep do i=1,22 !Expand the Q65 sync stride isync(i)=nint((isync(i)-1)*fac) + 1 enddo do i=1,63 jsync0(i)=2*(jsync0(i)-1) + 1 jsync1(i)=2*(jsync1(i)-1) + 1 enddo first=.false. endif df3=96000.0/NFFT ia=nint(1000*nfa/df3) + 1 !Flat frequency range for WSE converters ib=nint(1000*nfb/df3) + 1 npol=1 if(xpol) npol=4 do i=1,npol call pctile(savg(i,ia:ib),ib-ia+1,50,savg_med(i)) enddo ! do i=ia,ib ! write(14,3014) 0.001*(i-1)*df3,savg(1:npol,i) !3014 format(5f10.3) ! enddo lagbest=0 ipolbest=1 flip=0. do i=ia,ib ccfmax=0. do lag=0,LAGMAX ccf=0. ccf4=0. do j=1,22 !Test for Q65 sync k=isync(j) + lag ccf4=ccf4 + ss(1:npol,k,i+1) + ss(1:npol,k+1,i+1) + ss(1:npol,k+2,i+1) enddo ccf4=ccf4 - savg(1:npol,i+1)*3*22/float(jz) ccf=maxval(ccf4) ip=maxloc(ccf4) ipol=ip(1) if(ccf.gt.ccfmax) then ipolbest=ipol lagbest=lag ccfmax=ccf ccf4best=ccf4 flip=0. endif ccf=0. ccf4=0. do j=1,63 !Test for JT65 sync, std msg k=jsync0(j) + lag ccf4=ccf4 + ss(1:npol,k,i+1) + ss(1:npol,k+1,i+1) enddo ccf4=ccf4 - savg(1:npol,i+1)*2*63/float(jz) ccf=maxval(ccf4) ip=maxloc(ccf4) ipol=ip(1) if(ccf.gt.ccfmax) then ipolbest=ipol lagbest=lag ccfmax=ccf ccf4best=ccf4 flip=1.0 endif ccf=0. ccf4=0. do j=1,63 !Test for JT65 sync, OOO msg k=jsync1(j) + lag ccf4=ccf4 + ss(1:npol,k,i+1) + ss(1:npol,k+1,i+1) enddo ccf4=ccf4 - savg(1:npol,i+1)*2*63/float(jz) ccf=maxval(ccf4) ip=maxloc(ccf4) ipol=ip(1) if(ccf.gt.ccfmax) then ipolbest=ipol lagbest=lag ccfmax=ccf ccf4best=ccf4 flip=-1.0 endif enddo ! lag poldeg=0. if(xpol .and. ccfmax.ge.SNR1_THRESHOLD) then call polfit(ccf4best,4,a) poldeg=a(3) endif sync(i)%ccfmax=ccfmax sync(i)%xdt=lagbest*tstep-1.0 sync(i)%pol=poldeg sync(i)%ipol=ipolbest sync(i)%iflip=flip sync(i)%birdie=.false. if(ccfmax/(savg(ipolbest,i)/savg_med(ipolbest)).lt.3.0) sync(i)%birdie=.true. if(sync(i)%iflip.eq.0 .and. sync(i)%ccfmax .gt. 20.0) then write(50,3050) i,lagbest,sync(i)%ccfmax,sync(i)%xdt,sync(i)%ipol, & sync(i)%birdie,ccf4best 3050 format(2i5,f10.3,f8.2,i5,1x,L3,4f7.1) endif enddo ! i (frequency bin) ! do i=ia,ib ! write(15,3015) 0.001*(i-1)*df3,sync(i)%ccfmax,sync(i)%xdt,sync(i)%ipol, & ! sync(i)%iflip,sync(i)%birdie !3015 format(3f10.3,2i6,L5) ! enddo call pctile(sync(ia:ib)%ccfmax,ib-ia+1,50,base) sync(ia:ib)%ccfmax=sync(ia:ib)%ccfmax/base return end subroutine wb_sync end module wideband_sync