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https://github.com/saitohirga/WSJT-X.git
synced 2024-12-24 11:40:31 -05:00
Sorry, I did not intend to commit changes to these routines. Revert to 7305.
git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7307 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
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@ -99,7 +99,7 @@ contains
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if(nsubmode.ge.100) then
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! This is QRA64 mode
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mode64=2**(nsubmode-100)
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call qra64a(dd,npts,nutc,nf1,nf2,nfqso,ntol,mode64,mycall,hiscall, &
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call qra64a(dd,nutc,nf1,nf2,nfqso,ntol,mode64,mycall,hiscall, &
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hisgrid,sync,nsnr,dtx,nfreq,decoded,nft)
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if (associated(this%callback)) then
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ndrift=0
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@ -38,8 +38,7 @@ program qra64sim
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read(arg,*) nfiles
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call getarg(7,arg)
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read(arg,*) snrdb
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if(mode64.ge.8) nsigs=1
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rms=100.
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fsample=12000.d0 !Sample rate (Hz)
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dt=1.d0/fsample !Sample interval (s)
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@ -70,7 +69,6 @@ program qra64sim
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do isig=1,nsigs !Generate requested number of sigs
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if(mod(nsigs,2).eq.0) f0=1500.0 + dfsig*(isig-0.5-nsigs/2)
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if(mod(nsigs,2).eq.1) f0=1500.0 + dfsig*(isig-(nsigs+1)/2)
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if(mode64.ge.8) f0=700.0
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xsnr=snrdb
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if(snrdb.eq.0.0) xsnr=-20 - isig
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@ -1,15 +1,15 @@
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subroutine qra64a(dd,npts,nutc,nf1,nf2,nfqso,ntol,mode64,mycall_12,hiscall_12, &
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subroutine qra64a(dd,nutc,nf1,nf2,nfqso,ntol,mode64,mycall_12,hiscall_12, &
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hisgrid_6,sync,nsnr,dtx,nfreq,decoded,nft)
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use packjt
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parameter (NMAX=60*12000,LN=1152*63)
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parameter (NFFT=2*6912,NZ=5760,NMAX=60*12000,LN=1152*63)
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character decoded*22
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character*12 mycall_12,hiscall_12
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character*6 mycall,hiscall,hisgrid_6
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character*4 hisgrid
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logical ltext
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complex c00(0:720000) !Complex spectrum of dd()
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complex c0(0:720000) !Complex data for dd()
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complex c00(0:360000) !Complex spectrum of dd()
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complex c0(0:360000) !Complex spectrum of dd()
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! integer*8 count0,count1,clkfreq
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real a(3)
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real dd(NMAX) !Raw data sampled at 12000 Hz
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@ -30,7 +30,8 @@ subroutine qra64a(dd,npts,nutc,nf1,nf2,nfqso,ntol,mode64,mycall_12,hiscall_12, &
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call packcall(hiscall,nc2,ltext)
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call packgrid(hisgrid,ng2,ltext)
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nSubmode=nint(log(float(mode64)/log(2.0)))
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nFadingModel=1
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b90=1.0
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nFadingModel=0
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if(nc1.ne.nc1z .or. nc2.ne.nc2z .or. ng2.ne.ng2z) then
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do naptype=0,5
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call qra64_dec(s3,nc1,nc2,ng2,naptype,1,nSubmode,b90, &
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@ -41,32 +42,18 @@ subroutine qra64a(dd,npts,nutc,nf1,nf2,nfqso,ntol,mode64,mycall_12,hiscall_12, &
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ng2z=ng2
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endif
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maxf1=0
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call sync64(dd,npts,nf1,nf2,nfqso,ntol,mode64,maxf1,dtx,f0,jpk,kpk,snr1,c00)
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npts2=npts/2
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!###
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! dtx=0.
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! f0=1500.0
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! jpk=6000
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! kpk=0
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! if(mode64.ge.8) f0=700.0
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!###
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maxf1=5
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call sync64(dd,nf1,nf2,nfqso,ntol,mode64,maxf1,dtx,f0,jpk,kpk,snr1,c00)
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itz=10
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if(mode64.eq.4) itz=9
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if(mode64.eq.2) itz=7
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if(mode64.eq.1) itz=5
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npts2=216000
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naptype=4
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LL=64*(mode64+2)
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NN=63
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do itry0=1,7
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! do itry0=1,1
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! do itry0=1,3
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do itry0=1,1
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idf0=itry0/2
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if(mod(itry0,2).eq.0) idf0=-idf0
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! a(1)=-(f0+0.248*(idf0-0.33*kpk))
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a(1)=-(f0+1.736*(idf0-0.33*kpk))
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a(1)=-(f0+0.248*(idf0-0.33*kpk))
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nfreq=nint(-a(1))
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a(3)=0.
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! do itry1=1,3
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@ -74,18 +61,19 @@ subroutine qra64a(dd,npts,nutc,nf1,nf2,nfqso,ntol,mode64,mycall_12,hiscall_12, &
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idf1=itry1/2
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if(mod(itry1,2).eq.0) idf1=-idf1
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a(2)=-0.67*(idf1 + 0.67*kpk)
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call twkfreq(c00,c0,npts2,6000.0,a)
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call twkfreq(c00,c0,npts2,4000.0,a)
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call spec64(c0,npts2,mode64,jpk,s3a,LL,NN)
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ircmin=99
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do iter=itz,0,-1
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do iter=0,10
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b90=1.728**iter
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s3(1:LL*NN)=s3a(1:LL*NN)
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call qra64_dec(s3,nc1,nc2,ng2,naptype,0,nSubmode,b90, &
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nFadingModel,dat4,snr2,irc)
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if(irc.ge.0) write(*,3333) iter,idf0,-a(1),b90,irc
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3333 format(i2,i3,2f8.1,i3)
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if(abs(snr2).gt.30.) snr2=-30.0
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! if(irc.eq.0) go to 10
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if(irc.eq.0) go to 10
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! write(*,3001) iter,b90,snr2,irc
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! write(72,3001) iter,b90,snr2,irc
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!3001 format(i2,2f7.1,i4)
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if(irc.ge.0 .and. irc.le.ircmin) then
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dat4x=dat4
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b90x=b90
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@ -109,7 +97,12 @@ subroutine qra64a(dd,npts,nutc,nf1,nf2,nfqso,ntol,mode64,mycall_12,hiscall_12, &
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else
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snr2=0.
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endif
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! if(irc.ge.0) go to 900
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! write(78,3900) nutc,snr1,snr2,dtx,nfreq,kpk,idf0,idf1,irc,decoded
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!3900 format(i4.4,2f6.1,f6.2,i5,4i3,1x,a22)
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! flush(78)
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! write(*,3006) idf0,idf1,nfreq,jpk,kpk,irc,decoded
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!3006 format(2i4,i6,i7,2i4,2x,a22)
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if(irc.ge.0) go to 900
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enddo
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enddo
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900 continue
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@ -1,30 +1,31 @@
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subroutine spec64(c0,npts2,mode64,jpk,s3,LL,NN)
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parameter (NSPS=3456) !Samples per symbol at 6000 Hz
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parameter (NSPS=2304) !Samples per symbol at 4000 Hz
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complex c0(0:360000) !Complex spectrum of dd()
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complex cs(0:NSPS-1) !Complex symbol spectrum
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real s3(LL,NN) !Synchronized symbol spectra
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nfft6=nsps
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fac=1.0/nfft6
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do j=1,63
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jj=j+7 !Skip first Costas array
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if(j.ge.32) jj=j+14 !Skip middle Costas array
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ja=jpk + (jj-1)*nfft6
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jb=ja+nfft6-1
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cs(0:nfft6-1)=fac*c0(ja:jb)
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cs(0:nfft6-1)=c0(ja:jb)
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call four2a(cs,nfft6,1,-1,1)
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smax=0.
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do ii=1,LL
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i=ii-65
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if(i.lt.0) i=i+nfft6
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s3(ii,j)=real(cs(i))**2 + aimag(cs(i))**2
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if(s3(ii,j).gt.smax) then
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smax=s3(ii,j)
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ipk=ii-65
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endif
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enddo
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enddo
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! df=4000.0/nfft6
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! do i=1,LL
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! freq=(i-65)*df
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! write(73,3002) i-65,freq,(1.e-6*s3(i,j),j=1,5)
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!3002 format(i5,6f10.3)
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! enddo
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return
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end subroutine spec64
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@ -1,8 +1,7 @@
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subroutine sync64(dd,npts,nf1,nf2,nfqso,ntol,mode64,maxf1,dtx,f0,jpk,kpk, &
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snrdb,c0)
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subroutine sync64(dd,nf1,nf2,nfqso,ntol,mode64,maxf1,dtx,f0,jpk,kpk,snrdb,c0)
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parameter (NMAX=60*12000) !Max size of raw data at 12000 Hz
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parameter (NSPS=3456) !Samples per symbol at 6000 Hz
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parameter (NSPS=2304) !Samples per symbol at 4000 Hz
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parameter (NSPC=7*NSPS) !Samples per Costas array
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real dd(NMAX) !Raw data
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real s1(0:NSPC-1) !Power spectrum of Costas 1
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@ -15,7 +14,7 @@ subroutine sync64(dd,npts,nf1,nf2,nfqso,ntol,mode64,maxf1,dtx,f0,jpk,kpk, &
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integer icos7(0:6) !Costas 7x7 tones
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integer ipk0(1)
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complex cc(0:NSPC-1) !Costas waveform
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complex c0(0:720000) !Complex spectrum of dd()
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complex c0(0:360000) !Complex spectrum of dd()
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complex c1(0:NSPC-1) !Complex spectrum of Costas 1
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complex c2(0:NSPC-1) !Complex spectrum of Costas 2
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complex c3(0:NSPC-1) !Complex spectrum of Costas 3
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@ -32,8 +31,8 @@ subroutine sync64(dd,npts,nf1,nf2,nfqso,ntol,mode64,maxf1,dtx,f0,jpk,kpk, &
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k=-1
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phi=0.
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do j=0,6 !Compute complex Costas waveform
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dphi=twopi*nsync*icos7(j)*dfgen/6000.0
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do i=1,NSPS
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dphi=twopi*nsync*icos7(j)*dfgen/4000.0
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do i=1,2304
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phi=phi + dphi
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if(phi.gt.twopi) phi=phi-twopi
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k=k+1
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@ -43,20 +42,20 @@ subroutine sync64(dd,npts,nf1,nf2,nfqso,ntol,mode64,maxf1,dtx,f0,jpk,kpk, &
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mode64z=mode64
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endif
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npts0=54*12000
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nfft1=672000
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nfft2=nfft1/2
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nfft2=nfft1/3
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df1=12000.0/nfft1
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fac=2.0/nfft1
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c0(0:npts-1)=fac*dd(1:npts)
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c0(npts:nfft1)=0.
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call four2a(c0,nfft1,1,-1,1) !Forward c2c FFT
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c0(nfft2/2+1:nfft2)=0.
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c0(0)=0.5*c0(0)
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do i=0,nfft1/2 !Load real data into c0
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c0(i)=fac*cmplx(dd(1+2*i),dd(2+2*i))
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enddo
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call four2a(c0,nfft1,1,-1,0) !Forward r2c FFT
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call four2a(c0,nfft2,1,1,1) !Inverse c2c FFT; c0 is analytic sig
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npts2=npts/2 !Downsampled complex data length
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npts2=npts0/3 !Downsampled complex data length
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nfft3=NSPC
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nh3=nfft3/2
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df3=6000.0/nfft3
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df3=4000.0/nfft3
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fa=max(nf1,nfqso-ntol)
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fb=min(nf2,nfqso+ntol)
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ia=max(maxf1,nint(fa/df3))
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@ -65,7 +64,7 @@ subroutine sync64(dd,npts,nf1,nf2,nfqso,ntol,mode64,maxf1,dtx,f0,jpk,kpk, &
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snr=0.
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jpk=0
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ja=0
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jb=6*6000
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jb=6*4000
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jstep=200
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ka=-maxf1
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kb=maxf1
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@ -73,8 +72,8 @@ subroutine sync64(dd,npts,nf1,nf2,nfqso,ntol,mode64,maxf1,dtx,f0,jpk,kpk, &
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kpk=0
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do iter=1,2
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do j1=ja,jb,jstep
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j2=j1 + 39*NSPS
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j3=j1 + 77*NSPS
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j2=j1 + 39*2304
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j3=j1 + 77*2304
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c1=1.e-4*c0(j1:j1+NSPC-1) * conjg(cc)
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call four2a(c1,nfft3,1,-1,1)
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c2=1.e-4*c0(j2:j2+NSPC-1) * conjg(cc)
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@ -96,7 +95,7 @@ subroutine sync64(dd,npts,nf1,nf2,nfqso,ntol,mode64,maxf1,dtx,f0,jpk,kpk, &
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s0b(:ia-1)=0.
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s0b(ib+1:)=0.
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nadd=(7*mode64)/2
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if(mod(nadd,2).eq.0) nadd=nadd+1 !Make nadd odd
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if(mod(nadd,2).eq.1) nadd=nadd+1 !Make nadd odd
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if(nadd.ge.3) call smo(s0b(ia:ib),iz,s0(ia:ib),nadd)
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call smo121(s0(ia:ib),iz)
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nskip=max(14,2*mode64)
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@ -106,7 +105,7 @@ subroutine sync64(dd,npts,nf1,nf2,nfqso,ntol,mode64,maxf1,dtx,f0,jpk,kpk, &
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jpk=j1
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s0a=s0/rms
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snr=s
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dtx=jpk/6000.0 - 1.0
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dtx=jpk/4000.0 - 1.0
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ipk0=maxloc(s0(ia:ib))
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ipk=ipk0(1)
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f0=(ipk+ia-1)*df3
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