subroutine detectmsk40(cbig,n,mycall,hiscall,lines,nmessages, & nutc,ntol,t00) use timer_module, only: timer parameter (NSPM=240, NPTS=3*NSPM, MAXSTEPS=7500, NFFT=3*NSPM, MAXCAND=15) character*4 rpt(0:15) character*6 mycall,hiscall,mycall0,hiscall0 character*22 hashmsg,msgreceived character*80 lines(100) complex cbig(n) complex cdat(NPTS) !Analytic signal complex cdat2(NPTS) complex c(NSPM) complex ctmp(NFFT) complex cb(42) !Complex waveform for sync word complex cbr(42) !Complex waveform for reversed sync word complex cfac,cca,ccb complex ccr(NPTS) complex ccr1(NPTS) complex ccr2(NPTS) complex bb(6) integer s8(8),s8r(8),hardbits(40) integer, dimension(1) :: iloc ! integer nhashes(0:15) integer indices(MAXSTEPS) integer ipeaks(10) integer*1 cw(32) integer*1 decoded(16) integer*1 testcw(32) logical ismask(NFFT) real cbi(42),cbq(42) real detmet(-2:MAXSTEPS+3) real detmet2(-2:MAXSTEPS+3) real detfer(MAXSTEPS) real rcw(12) real ddr(NPTS) real ferrs(MAXCAND) real llr(32) real pp(12) !Half-sine pulse shape real snrs(MAXCAND) real softbits(40) real times(MAXCAND) real tonespec(NFFT) real*8 dt, df, fs, pi, twopi real*8 lratio(32) logical first data first/.true./ data mycall0/'dummy'/,hiscall0/'dummy'/ data rpt/"-03 ","+00 ","+03 ","+06 ","+10 ","+13 ","+16 ", & "R-03","R+00","R+03","R+06","R+10","R+13","R+16", & "RRR ","73 "/ data s8/0,1,1,1,0,0,1,0/ data s8r/1,0,1,1,0,0,0,1/ ! codeword for the message RRR data testcw/0,1,0,0,0,1,0,1,0,0,1,1,1,1,0,1,0,1,1,1,1,1,0,0,0,0,0,0,1,1,1,0/ save df,first,cb,cbr,fs,pi,twopi,dt,s8,s8r,rcw,pp,nmatchedfilter,rpt,mycall0,hiscall0,ihash if(first) then nmatchedfilter=1 ! define half-sine pulse and raised-cosine edge window pi=4d0*datan(1d0) twopi=8d0*datan(1d0) fs=12000.0 dt=1.0/fs df=fs/NFFT do i=1,12 angle=(i-1)*pi/12.0 pp(i)=sin(angle) rcw(i)=(1-cos(angle))/2 enddo ! define the sync word waveforms s8=2*s8-1 cbq(1:6)=pp(7:12)*s8(1) cbq(7:18)=pp*s8(3) cbq(19:30)=pp*s8(5) cbq(31:42)=pp*s8(7) cbi(1:12)=pp*s8(2) cbi(13:24)=pp*s8(4) cbi(25:36)=pp*s8(6) cbi(37:42)=pp(1:6)*s8(8) cb=cmplx(cbi,cbq) s8r=2*s8r-1 cbq(1:6)=pp(7:12)*s8r(1) cbq(7:18)=pp*s8r(3) cbq(19:30)=pp*s8r(5) cbq(31:42)=pp*s8r(7) cbi(1:12)=pp*s8r(2) cbi(13:24)=pp*s8r(4) cbi(25:36)=pp*s8r(6) cbi(37:42)=pp(1:6)*s8r(8) cbr=cmplx(cbi,cbq) first=.false. endif if(mycall.ne.mycall0 .or. hiscall.ne.hiscall0) then ! do i=0,15 ! hashmsg=trim(mycall)//' '//trim(hiscall)//' '//rpt(i) hashmsg=trim(mycall)//' '//trim(hiscall) call fmtmsg(hashmsg,iz) call hash(hashmsg,22,ihash) ! nhashes(i)=iand(ihash,4095) ihash=iand(ihash,4095) ! enddo mycall0=mycall hiscall0=hiscall endif ! Fill the detmet, detferr arrays nstepsize=60 ! 5ms steps nstep=(n-NPTS)/nstepsize detmet=0 detmet2=0 detfer=-999.99 do istp=1,nstep ns=1+nstepsize*(istp-1) ne=ns+NPTS-1 if( ne .gt. n ) exit ctmp=cmplx(0.0,0.0) ctmp(1:NPTS)=cbig(ns:ne) ! Coarse carrier frequency sync - seek tones at 2000 Hz and 4000 Hz in ! squared signal spectrum. ! search range for coarse frequency error is +/- 100 Hz ctmp=ctmp**2 ctmp(1:12)=ctmp(1:12)*rcw ctmp(NPTS-11:NPTS)=ctmp(NPTS-11:NPTS)*rcw(12:1:-1) call four2a(ctmp,NFFT,1,-1,1) tonespec=abs(ctmp)**2 ihlo=(4000-2*ntol)/df+1 ihhi=(4000+2*ntol)/df+1 ismask=.false. ismask(ihlo:ihhi)=.true. ! high tone search window iloc=maxloc(tonespec,ismask) ihpk=iloc(1) deltah=-real( (ctmp(ihpk-1)-ctmp(ihpk+1)) / (2*ctmp(ihpk)-ctmp(ihpk-1)-ctmp(ihpk+1)) ) ah=tonespec(ihpk) ahavp=(sum(tonespec,ismask)-ah)/count(ismask) trath=ah/(ahavp+0.01) illo=(2000-2*ntol)/df+1 ilhi=(2000+2*ntol)/df+1 ismask=.false. ismask(illo:ilhi)=.true. ! window for low tone iloc=maxloc(tonespec,ismask) ilpk=iloc(1) deltal=-real( (ctmp(ilpk-1)-ctmp(ilpk+1)) / (2*ctmp(ilpk)-ctmp(ilpk-1)-ctmp(ilpk+1)) ) al=tonespec(ilpk) alavp=(sum(tonespec,ismask)-al)/count(ismask) tratl=al/(alavp+0.01) fdiff=(ihpk+deltah-ilpk-deltal)*df i2000=nint(2000/df)+1 i4000=nint(4000/df)+1 ferrh=(ihpk+deltah-i4000)*df/2.0 ferrl=(ilpk+deltal-i2000)*df/2.0 if( ah .ge. al ) then ferr=ferrh else ferr=ferrl endif detmet(istp)=max(ah,al) detmet2(istp)=max(trath,tratl) detfer(istp)=ferr ! write(*,*) istp,ilpk,ihpk,ah,al enddo ! end of detection-metric and frequency error estimation loop call indexx(detmet(1:nstep),nstep,indices) !find median of detection metric vector xmed=detmet(indices(nstep/4)) detmet=detmet/xmed ! noise floor of detection metric is 1.0 ndet=0 !do i=1,nstep !write(77,*) i,detmet(i),detmet2(i),detfer(i) !enddo do ip=1,MAXCAND ! find candidates iloc=maxloc(detmet(1:nstep)) il=iloc(1) if( (detmet(il) .lt. 4.2) ) exit if( abs(detfer(il)) .le. ntol ) then ndet=ndet+1 times(ndet)=((il-1)*nstepsize+NPTS/2)*dt ferrs(ndet)=detfer(il) snrs(ndet)=12.0*log10(detmet(il)-1)/2-8.0 endif detmet(max(1,il-3):min(nstep,il+3))=0.0 ! detmet(il)=0.0 enddo if( ndet .lt. 3 ) then do ip=1,MAXCAND-ndet ! Find candidates iloc=maxloc(detmet2(1:nstep)) il=iloc(1) if( (detmet2(il) .lt. 20.0) ) exit if( abs(detfer(il)) .le. ntol ) then ndet=ndet+1 times(ndet)=((il-1)*nstepsize+NSPM/2)*dt ferrs(ndet)=detfer(il) snrs(ndet)=12.0*log10(detmet2(il))/2-9.0 endif detmet2(max(1,il-1):min(nstep,il+1))=0.0 ! detmet2(il)=0.0 enddo endif ! do ip=1,ndet ! write(*,'(i5,f7.2,f7.2,f7.2)') ip,times(ip),snrs(ip),ferrs(ip) ! enddo nmessages=0 lines=char(0) ncalls=0 do ip=1,ndet !run through the candidates and try to sync/demod/decode imid=times(ip)*fs if( imid .lt. NPTS/2 ) imid=NPTS/2 if( imid .gt. n-NPTS/2 ) imid=n-NPTS/2 t0=times(ip) + t00 cdat=cbig(imid-NPTS/2+1:imid+NPTS/2) ferr=ferrs(ip) xsnr=snrs(ip) nsnr=nint(snrs(ip)) if( nsnr .lt. -5 ) nsnr=-5 if( nsnr .gt. 25 ) nsnr=25 ! remove coarse freq error call tweak1(cdat,NPTS,-(1500+ferr),cdat) ! attempt frame synchronization ! correlate with sync word waveforms ccr=0 ccr1=0 ccr2=0 do i=1,NPTS-(40*6+41) ccr1(i)=sum(cdat(i:i+41)*conjg(cbr)) ccr2(i)=sum(cdat(i+40*6:i+40*6+41)*conjg(cbr)) enddo ccr=ccr1+ccr2 ddr=abs(ccr1)*abs(ccr2) crmax=maxval(abs(ccr)) !do i=1,NPTS !write(15,*) i,abs(ccr(i)),ddr(i),abs(cdat(i)) !enddo ! Find 6 largest peaks do ipk=1,6 iloc=maxloc(ddr) ic1=iloc(1) ipeaks(ipk)=ic1 ddr(max(1,ic1-7):min(NPTS-40*6-41,ic1+7))=0.0 enddo !do i=1,6 !write(*,*) i,ipeaks(i) !enddo do ipk=1,4 ! we want ic to be the index of the first sample of the frame ic0=ipeaks(ipk) ! fine adjustment of sync index do i=1,6 if( ic0+11+NSPM .le. NPTS ) then bb(i) = sum( ( cdat(ic0+i-1+6:ic0+i-1+6+NSPM:6) * conjg( cdat(ic0+i-1:ic0+i-1+NSPM:6) ) )**2 ) else bb(i) = sum( ( cdat(ic0+i-1+6:NPTS:6) * conjg( cdat(ic0+i-1:NPTS-6:6) ) )**2 ) endif enddo iloc=maxloc(abs(bb)) ibb=iloc(1) bba=abs(bb(ibb)) bbp=atan2(-imag(bb(ibb)),-real(bb(ibb)))/(2*twopi*6*dt) !write(*,*) abs(bb),bbp if( ibb .le. 3 ) ibb=ibb-1 if( ibb .gt. 3 ) ibb=ibb-7 do id=1,3 ! slicer dither. if( id .eq. 1 ) is=0 if( id .eq. 2 ) is=-1 if( id .eq. 3 ) is=1 ! Adjust frame index to place peak of bb at desired lag ic=ic0+ibb+is if( ic .lt. 1 ) ic=ic+NSPM ! Estimate fine frequency error. cca=sum(cdat(ic:ic+41)*conjg(cbr)) if( ic+40*6+41 .le. NPTS ) then ccb=sum(cdat(ic+40*6:ic+40*6+41)*conjg(cbr)) cfac=ccb*conjg(cca) ferr2=atan2(imag(cfac),real(cfac))/(twopi*40*6*dt) else ccb=sum(cdat(ic-40*6:ic-40*6+41)*conjg(cbr)) cfac=cca*conjg(ccb) ferr2=atan2(imag(cfac),real(cfac))/(twopi*40*6*dt) endif do idf=0,2 ! frequency jitter if( idf .eq. 0 ) then deltaf=0.0 elseif( mod(idf,2) .eq. 0 ) then deltaf=2.5*idf else deltaf=-2.5*(idf+1) endif ! Remove fine frequency error call tweak1(cdat,NPTS,-(ferr2+deltaf),cdat2) ! place the beginning of frame at index NSPM+1 cdat2=cshift(cdat2,ic-(NSPM+1)) do iav=1,4 ! Frame averaging patterns if( iav .eq. 1 ) then c=cdat2(NSPM+1:2*NSPM) elseif( iav .eq. 2 ) then c=cdat2(1:NSPM)+cdat2(NSPM+1:2*NSPM) elseif( iav .eq. 3 ) then c=cdat2(NSPM+1:2*NSPM)+cdat2(2*NSPM+1:3*NSPM) elseif( iav .eq. 4 ) then c=cdat2(1:NSPM)+cdat2(NSPM+1:2*NSPM)+cdat2(2*NSPM+1:3*NSPM) endif ! Estimate final frequency error and carrier phase. cca=sum(c(1:1+41)*conjg(cbr)) phase0=atan2(imag(cca),real(cca)) do ipha=1,3 if( ipha.eq.2 ) phase0=phase0-30*pi/180.0 if( ipha.eq.3 ) phase0=phase0+30*pi/180.0 ! Remove phase error - want constellation rotated so that sample points lie on I/Q axes cfac=cmplx(cos(phase0),sin(phase0)) c=c*conjg(cfac) if( nmatchedfilter .eq. 0 ) then do i=1, 20 softbits(2*i-1)=imag(c(1+(i-1)*12)) softbits(2*i)=real(c(7+(i-1)*12)) enddo else ! matched filter softbits(1)=sum(imag(c(1:6))*pp(7:12))+sum(imag(c(NSPM-5:NSPM))*pp(1:6)) softbits(2)=sum(real(c(1:12))*pp) do i=2,20 softbits(2*i-1)=sum(imag(c(1+(i-1)*12-6:1+(i-1)*12+5))*pp) softbits(2*i)=sum(real(c(7+(i-1)*12-6:7+(i-1)*12+5))*pp) enddo endif hardbits=0 ! use sync word hard error weight to decide whether to send to decoder do i=1, 40 if( softbits(i) .ge. 0.0 ) then hardbits(i)=1 endif enddo nbadsync1=(8-sum( (2*hardbits(1:8)-1)*s8r ) )/2 nbadsync=nbadsync1 if( nbadsync .gt. 3 ) cycle ! nerr=0 ! do i=1,32 ! if( testcw(i) .ne. hardbits(i+8) ) nerr=nerr+1 ! enddo ! normalize the softsymbols before submitting to decoder sav=sum(softbits)/40 s2av=sum(softbits*softbits)/40 ssig=sqrt(s2av-sav*sav) softbits=softbits/ssig sigma=0.75 if(xsnr.lt.0.0) sigma=0.75-0.0875*xsnr lratio(1:32)=exp(2.0*softbits(9:40)/(sigma*sigma)) ! Use this for Radford Neal's routines llr(1:32)=2.0*softbits(9:40)/(sigma*sigma) ! Use log likelihood for bpdecode40 max_iterations=5 max_dither=1 call bpdecode40(llr,max_iterations, decoded, niterations) ncalls=ncalls+1 nhashflag=0 if( niterations .ge. 0 ) then call encode_msk40(decoded,cw) ! call ldpc_encode(decoded,cw) nhammd=0 cord=0.0 do i=1,32 if( cw(i) .ne. hardbits(i+8) ) then nhammd=nhammd+1 cord=cord+abs(softbits(i+8)) endif enddo imsg=0 do i=1,16 imsg=ishft(imsg,1)+iand(1,decoded(17-i)) enddo nrxrpt=iand(imsg,15) nrxhash=(imsg-nrxrpt)/16 ! if( nhammd .le. 5 .and. cord .lt. 1.7 .and. nrxhash .eq. nhashes(nrxrpt) ) then if( nhammd .le. 5 .and. cord .lt. 1.7 .and. nrxhash .eq. ihash ) then fest=1500+ferr+ferr2+deltaf !write(14,'(i6.6,11i6,f7.1,f7.1)') nutc,ip,ipk,id,idf,iav,ipha,niterations,nbadsync,nrxrpt,ncalls,nhammd,cord,xsnr nhashflag=1 msgreceived=' ' nmessages=1 write(msgreceived,'(a1,a,1x,a,a1,1x,a4)') "<",trim(mycall), & trim(hiscall),">",rpt(nrxrpt) write(lines(nmessages),1020) nutc,nsnr,t0,nint(fest),msgreceived 1020 format(i6.6,i4,f5.1,i5,' & ',a22) return endif endif enddo ! phase loop enddo ! frame averaging loop enddo ! frequency dithering loop enddo ! slicer dither loop enddo ! time-sync correlation-peak loop enddo ! candidate loop return end subroutine detectmsk40