WSJT-X/lib/detectmsk144.f90
Steven Franke d39dfe3d87 Catch up msk144d.f90 with recent changes. Implement FTol in detectmsk144 (but not in detectmsk32 yet).
git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6899 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-07-09 00:07:07 +00:00

405 lines
13 KiB
Fortran

subroutine detectmsk144(cbig,n,pchk_file,lines,nmessages,nutc,ntol)
use timer_module, only: timer
parameter (NSPM=864, NPTS=3*NSPM, MAXSTEPS=1700, NFFT=NSPM, MAXCAND=12)
character*22 msgreceived,allmessages(20)
character*80 lines(100)
character*512 pchk_file,gen_file
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 cc(NPTS)
complex ccr(NPTS)
complex cc1(NPTS)
complex cc2(NPTS)
complex ccr1(NPTS)
complex ccr2(NPTS)
complex bb(6)
integer s8(8),s8r(8),hardbits(144)
integer, dimension(1) :: iloc
integer*1 decoded(80)
integer indices(MAXSTEPS)
integer ipeaks(10)
logical ismask(NFFT)
real cbi(42),cbq(42)
real detmet(-2:MAXSTEPS+3)
real detfer(MAXSTEPS)
real rcw(12)
real dd(NPTS)
real ddr(NPTS)
real ferrs(MAXCAND)
real pp(12) !Half-sine pulse shape
real snrs(MAXCAND)
real times(MAXCAND)
real tonespec(NFFT)
real*8 dt, df, fs, pi, twopi
real softbits(144)
real*8 unscrambledsoftbits(128)
real lratio(128)
logical first
data first/.true./
data s8/0,1,1,1,0,0,1,0/
data s8r/1,0,1,1,0,0,0,1/
save df,first,cb,fs,pi,twopi,dt,s8,rcw,pp,nmatchedfilter
if(first) then
nmatchedfilter=1
i=index(pchk_file,".pchk")
gen_file=pchk_file(1:i-1)//".gen"
call init_ldpc(trim(pchk_file)//char(0),trim(gen_file)//char(0))
! 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
! fill the detmet, detferr arrays
nstep=(n-NPTS)/216 ! 72ms/4=18ms steps
detmet=0
detmax=-999.99
detfer=-999.99
do istp=1,nstep
ns=1+216*(istp-1)
ne=ns+NSPM-1
if( ne .gt. n ) exit
ctmp=cmplx(0.0,0.0)
ctmp(1:NSPM)=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(NSPM-11:NSPM)=ctmp(NSPM-11:NSPM)*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)
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)
fdiff=(ihpk+deltah-ilpk-deltal)*df
i2000=2000/df+1
i4000=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)
detfer(istp)=ferr
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 ip=1,MAXCAND ! Find candidates
iloc=maxloc(detmet(1:nstep))
il=iloc(1)
if( (detmet(il) .lt. 3.5) ) exit
if( abs(detfer(il)) .le. ntol ) then
ndet=ndet+1
times(ndet)=((il-1)*216+NSPM/2)*dt
ferrs(ndet)=detfer(il)
snrs(ndet)=12.0*log10(detmet(il))/2-9.0
endif
! detmet(max(1,il-2):min(nstep,il+2))=0.0
detmet(il)=0.0
enddo
nmessages=0
allmessages=char(0)
lines=char(0)
do ip=1,ndet ! Try to sync/demod/decode each candidate.
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)
cdat=cbig(imid-NPTS/2+1:imid+NPTS/2)
ferr=ferrs(ip)
nsnr=snrs(ip)
! remove coarse freq error - should now be within a few Hz
call tweak1(cdat,NPTS,-(1500+ferr),cdat)
! attempt frame synchronization
! correlate with sync word waveforms
cc=0
ccr=0
cc1=0
cc2=0
ccr1=0
ccr2=0
do i=1,NPTS-(56*6+41)
cc1(i)=sum(cdat(i:i+41)*conjg(cb))
cc2(i)=sum(cdat(i+56*6:i+56*6+41)*conjg(cb))
enddo
cc=cc1+cc2
dd=abs(cc1)*abs(cc2)
do i=1,NPTS-(32*6+41)
ccr1(i)=sum(cdat(i:i+41)*conjg(cbr))
ccr2(i)=sum(cdat(i+32*6:i+32*6+41)*conjg(cbr))
enddo
ccr=ccr1+ccr2
ddr=abs(ccr1)*abs(ccr2)
cmax=maxval(abs(cc))
crmax=maxval(abs(ccr))
ishort=0
if( crmax .gt. cmax ) ishort=1
! Find 6 largest peaks
do ipk=1, 6
iloc=maxloc(abs(cc))
ic1=iloc(1)
iloc=maxloc(dd)
ic2=iloc(1)
ipeaks(ipk)=ic2
dd(max(1,ic2-7):min(NPTS-56*6-41,ic2+7))=0.0
! ipeaks(ipk)=ic1
! cc(max(1,ic1-7):min(NPTS-56*6-41,ic1+7))=0.0
!write(*,*) ipk,ic2
enddo
do ipk=1,6
! 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)
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+864
! Estimate fine frequency error.
! Should a larger separation be used when frames are averaged?
cca=sum(cdat(ic:ic+41)*conjg(cb))
if( ic+56*6+41 .le. NPTS ) then
ccb=sum(cdat(ic+56*6:ic+56*6+41)*conjg(cb))
cfac=ccb*conjg(cca)
ferr2=atan2(imag(cfac),real(cfac))/(twopi*56*6*dt)
else
ccb=sum(cdat(ic-88*6:ic-88*6+41)*conjg(cb))
cfac=cca*conjg(ccb)
ferr2=atan2(imag(cfac),real(cfac))/(twopi*88*6*dt)
endif
! Final estimate of the carrier frequency - returned to the calling program
fest=1500+ferr+ferr2
do idf=0,6 ! frequency jitter
if( idf .eq. 0 ) then
deltaf=0.0
elseif( mod(idf,2) .eq. 0 ) then
deltaf=idf
else
deltaf=-(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=1,8 ! Hopefully we can eliminate some of these after looking at more examples
if( iav .eq. 1 ) then
c=cdat2(NSPM+1:2*NSPM)
elseif( iav .eq. 2 ) then
c=cdat2(NSPM-431:NSPM+432)
c=cshift(c,-432)
elseif( iav .eq. 3 ) then
c=cdat2(2*NSPM-431:2*NSPM+432)
c=cshift(c,-432)
elseif( iav .eq. 4 ) then
c=cdat2(1:NSPM)
elseif( iav .eq. 5 ) then
c=cdat2(2*NSPM+1:NPTS)
elseif( iav .eq. 6 ) then
c=cdat2(1:NSPM)+cdat2(NSPM+1:2*NSPM)
elseif( iav .eq. 7 ) then
c=cdat2(NSPM+1:2*NSPM)+cdat2(2*NSPM+1:NPTS)
elseif( iav .eq. 8 ) then
c=cdat2(1:NSPM)+cdat2(NSPM+1:2*NSPM)+cdat2(2*NSPM+1:NPTS)
endif
! Estimate final frequency error and carrier phase.
cca=sum(c(1:1+41)*conjg(cb))
ccb=sum(c(1+56*6:1+56*6+41)*conjg(cb))
cfac=ccb*conjg(cca)
ffin=atan2(imag(cfac),real(cfac))/(twopi*56*6*dt)
phase0=atan2(imag(cca+ccb),real(cca+ccb))
do ipha=1,1
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
! sample to get softsamples
do i=1,72
softbits(2*i-1)=imag(c(1+(i-1)*12))
softbits(2*i)=real(c(7+(i-1)*12))
enddo
else
! matched filter -
! how much mismatch does the RX/TX/analytic filter cause?, how rig (pair) dependent is this loss?
softbits(1)=sum(imag(c(1:6))*pp(7:12))+sum(imag(c(864-5:864))*pp(1:6))
softbits(2)=sum(real(c(1:12))*pp)
do i=2,72
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
! sync word hard error weight is a good discriminator for
! frames that have reasonable probability of decoding
hardbits=0
do i=1,144
if( softbits(i) .ge. 0.0 ) then
hardbits(i)=1
endif
enddo
nbadsync1=(8-sum( (2*hardbits(1:8)-1)*s8 ) )/2
nbadsync2=(8-sum( (2*hardbits(1+56:8+56)-1)*s8 ) )/2
nbadsync=nbadsync1+nbadsync2
if( nbadsync .gt. 4 ) cycle
! normalize the softsymbols before submitting to decoder
sav=sum(softbits)/144
s2av=sum(softbits*softbits)/144
ssig=sqrt(s2av-sav*sav)
softbits=softbits/ssig
sigma=0.75
lratio(1:48)=softbits(9:9+47)
lratio(49:128)=softbits(65:65+80-1)
lratio=exp(2.0*lratio/(sigma*sigma))
unscrambledsoftbits(1:127:2)=lratio(1:64)
unscrambledsoftbits(2:128:2)=lratio(65:128)
max_iterations=10
max_dither=1
call ldpc_decode(unscrambledsoftbits, decoded, &
max_iterations, niterations, max_dither, ndither)
if( niterations .ge. 0.0 ) then
call extractmessage144(decoded,msgreceived,nhashflag)
if( nhashflag .gt. 0 ) then ! CRCs match, so print it
ndupe=0
do im=1,nmessages
if( allmessages(im) .eq. msgreceived ) ndupe=1
enddo
if( ndupe .eq. 0 ) then
nmessages=nmessages+1
allmessages(nmessages)=msgreceived
write(lines(nmessages),1020) nutc,nsnr,t0,nint(fest),msgreceived
1020 format(i6.6,i4,f5.1,i5,' & ',a22)
endif
goto 999
else
msgreceived=' '
ndither=-99 ! -99 is bad hash flag
! write(78,1001) nutc,t0,nsnr,ip,ipk,is,idf,iav,ipha,deltaf,fest,ferr,ferr2, &
! ffin,bba,bbp,nbadsync1,nbadsync2, &
! phase0,niterations,ndither,msgreceived
endif
endif
enddo ! phase dither
enddo ! frame averaging loop
enddo ! frequency dithering loop
enddo ! sample-time dither loop
enddo ! peak loop - could be made more efficient by working harder to find good peaks
msgreceived=' '
ndither=-98
999 continue
if( nmessages .ge. 1 ) then
! write(78,1001) nutc,t0,nsnr,ip,ipk,is,idf,iav,ipha,deltaf,fest,ferr,ferr2, &
! ffin,bba,bbp,nbadsync1,nbadsync2, &
! phase0,niterations,ndither,msgreceived
! call flush(78)
!1001 format(i6.6,f8.2,i5,i5,i5,i5,i5,i5,i5,f6.2,f8.2,f8.2,f8.2,f8.2,f11.1,f8.2,i5,i5,f8.2,i5,i5,2x,a22)
exit
endif
enddo
return
end subroutine detectmsk144