subroutine ft8b_2(dd0,newdat,nQSOProgress,nfqso,nftx,ndepth,lapon,lapcqonly, & napwid,lsubtract,nagain,iaptype,mycall12,hiscall12, & sync0,f1,xdt,xbase,apsym,nharderrors,dmin,nbadcrc,ipass,iera,msg37,xsnr) use crc use timer_module, only: timer use packjt77 include 'ft8_params.f90' parameter(NP2=2812) character*37 msg37,msgsent37 character*12 mycall12,hiscall12,hiscall12_0 character*77 c77 character*6 mycall6,hiscall6,c1,c2 character*13 c13 character*87 cbits real a(5) real s8(0:7,NN) real s2(0:511),s2l(0:511) real bmeta(3*ND),bmetb(3*ND),bmetc(3*ND) real bmetal(3*ND),bmetbl(3*ND),bmetcl(3*ND) real llra(3*ND),llrb(3*ND),llrc(3*ND),llrd(3*ND) !Soft symbols real llral(3*ND),llrbl(3*ND),llrcl(3*ND) !Soft symbols real dd0(15*12000) integer*1 message77(77),apmask(3*ND),cw(3*ND) integer*1 msgbits(77) integer apsym(77) integer mcq(29),mrrr(19),m73(19),mrr73(19) integer itone(NN) integer icos7(0:6),ip(1) integer nappasses(0:5) !Number of decoding passes to use for each QSO state integer naptypes(0:5,4) ! (nQSOProgress, decoding pass) maximum of 4 passes for now integer*1, target:: i1hiscall(12) logical one(0:511,0:8) integer graymap(0:7) complex cd0(0:3199) complex ctwk(32) complex csymb(32) complex cs(0:7,NN) logical first,newdat,lsubtract,lapon,lapcqonly,nagain,unpk77_success data icos7/3,1,4,0,6,5,2/ ! Flipped w.r.t. original FT8 sync array data mcq/0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,1,0,0/ data mrrr/0,1,1,1,1,1,1,0,1,0,0,1,0,0,1,0,0,0,1/ data m73/0,1,1,1,1,1,1,0,1,0,0,1,0,1,0,0,0,0,1/ data mrr73/0,1,1,1,1,1,1,0,0,1,1,1,0,1,0,1,0,0,1/ data first/.true./ data graymap/0,1,3,2,5,6,4,7/ save nappasses,naptypes,one,hiscall12_0 if(first) then mcq=2*mcq-1 mrrr=2*mrrr-1 m73=2*m73-1 mrr73=2*mrr73-1 nappasses(0)=2 nappasses(1)=2 nappasses(2)=2 nappasses(3)=4 nappasses(4)=4 nappasses(5)=3 ! iaptype !------------------------ ! 1 CQ ??? ??? (29+3=32 ap bits) ! 2 MyCall ??? ??? (29+3=32 ap bits) ! 3 MyCall DxCall ??? (58+3=61 ap bits) ! 4 MyCall DxCall RRR (77 ap bits) ! 5 MyCall DxCall 73 (77 ap bits) ! 6 MyCall DxCall RR73 (77 ap bits) naptypes(0,1:4)=(/1,2,0,0/) naptypes(1,1:4)=(/2,3,0,0/) naptypes(2,1:4)=(/2,3,0,0/) naptypes(3,1:4)=(/3,4,5,6/) naptypes(4,1:4)=(/3,4,5,6/) naptypes(5,1:4)=(/3,1,2,0/) one=.false. do i=0,511 do j=0,8 if(iand(i,2**j).ne.0) one(i,j)=.true. enddo enddo first=.false. endif if(hiscall12.ne.hiscall12_0) then c13=hiscall12//' ' call save_hash_call(c13,n10,n12,n22) hiscall12_0=hiscall12 endif max_iterations=30 nharderrors=-1 nbadcrc=1 ! this is used upstream to flag good decodes. fs2=12000.0/NDOWN dt2=1.0/fs2 twopi=8.0*atan(1.0) delfbest=0. ibest=0 call timer('ft8_down',0) call ft8_downsample(dd0,newdat,f1,cd0) !Mix f1 to baseband and downsample call timer('ft8_down',1) i0=nint((xdt+0.5)*fs2) !Initial guess for start of signal smax=0.0 do idt=i0-8,i0+8 !Search over +/- one quarter symbol call sync8d(cd0,idt,ctwk,0,2,sync) if(sync.gt.smax) then smax=sync ibest=idt endif enddo xdt2=ibest*dt2 !Improved estimate for DT ! Now peak up in frequency i0=nint(xdt2*fs2) smax=0.0 do ifr=-5,5 !Search over +/- 2.5 Hz delf=ifr*0.5 dphi=twopi*delf*dt2 phi=0.0 do i=1,32 ctwk(i)=cmplx(cos(phi),sin(phi)) phi=mod(phi+dphi,twopi) enddo call sync8d(cd0,i0,ctwk,1,2,sync) if( sync .gt. smax ) then smax=sync delfbest=delf endif enddo a=0.0 a(1)=-delfbest call twkfreq1(cd0,NP2,fs2,a,cd0) xdt=xdt2 f1=f1+delfbest !Improved estimate of DF call sync8d(cd0,i0,ctwk,0,2,sync) do k=1,NN i1=ibest+(k-1)*32 csymb=cmplx(0.0,0.0) if( i1.ge.0 .and. i1+31 .le. NP2-1 ) csymb=cd0(i1:i1+31) call four2a(csymb,32,1,-1,1) cs(0:7,k)=csymb(1:8)/1e3 s8(0:7,k)=abs(csymb(1:8)) enddo ! sync quality check is1=0 is2=0 is3=0 do k=1,7 ip=maxloc(s8(:,k)) if(icos7(k-1).eq.(ip(1)-1)) is1=is1+1 ip=maxloc(s8(:,k+36)) if(icos7(k-1).eq.(ip(1)-1)) is2=is2+1 ip=maxloc(s8(:,k+72)) if(icos7(k-1).eq.(ip(1)-1)) is3=is3+1 enddo ! hard sync sum - max is 21 nsync=is1+is2+is3 if(nsync .le. 6) then ! bail out nbadcrc=1 return endif do nsym=1,3 nt=2**(3*nsym) do ihalf=1,2 do k=1,29,nsym if(ihalf.eq.1) ks=k+7 if(ihalf.eq.2) ks=k+43 amax=-1.0 do i=0,nt-1 i1=i/64 i2=iand(i,63)/8 i3=iand(i,7) if(nsym.eq.1) then s2(i)=abs(cs(graymap(i3),ks)) elseif(nsym.eq.2) then s2(i)=abs(cs(graymap(i2),ks)+cs(graymap(i3),ks+1)) elseif(nsym.eq.3) then s2(i)=abs(cs(graymap(i1),ks)+cs(graymap(i2),ks+1)+cs(graymap(i3),ks+2)) else print*,"Error - nsym must be 1, 2, or 3." endif enddo s2l(0:nt-1)=log(s2(0:nt-1)+1e-32) i32=1+(k-1)*3+(ihalf-1)*87 if(nsym.eq.1) ibmax=2 if(nsym.eq.2) ibmax=5 if(nsym.eq.3) ibmax=8 do ib=0,ibmax bm=maxval(s2(0:nt-1),one(0:nt-1,ibmax-ib)) - & maxval(s2(0:nt-1),.not.one(0:nt-1,ibmax-ib)) ! bml=maxval(s2l(0:nt-1),one(0:nt-1,ibmax-ib)) - & ! maxval(s2l(0:nt-1),.not.one(0:nt-1,ibmax-ib)) if(i32+ib .gt.174) cycle if(nsym.eq.1) then bmeta(i32+ib)=bm ! bmetal(i32+ib)=bml elseif(nsym.eq.2) then bmetb(i32+ib)=bm ! bmetbl(i32+ib)=bml elseif(nsym.eq.3) then bmetc(i32+ib)=bm ! bmetcl(i32+ib)=bml endif enddo enddo enddo enddo call normalizebmet(bmeta,3*ND) ! call normalizebmet(bmetal,3*ND) call normalizebmet(bmetb,3*ND) ! call normalizebmet(bmetbl,3*ND) call normalizebmet(bmetc,3*ND) ! call normalizebmet(bmetcl,3*ND) scalefac=2.83 llra=scalefac*bmeta ! llral=scalefac*bmetal llrb=scalefac*bmetb ! llrbl=scalefac*bmetbl llrc=scalefac*bmetc ! llrcl=scalefac*bmetcl apmag=maxval(abs(llrb))*1.01 ! pass # !------------------------------ ! 1 regular decoding, nsym=1 ! 2 regular decoding, nsym=2 ! 3 regular decoding, nsym=3 ! 4 ap pass 1, nsym=1 (for now?) ! 5 ap pass 2 ! 6 ap pass 3 ! 7 ap pass 4 if(lapon) then if(.not.lapcqonly) then npasses=3+nappasses(nQSOProgress) else npasses=4 endif else npasses=3 endif do ipass=1,npasses llrd=llra if(ipass.eq.2) llrd=llrb if(ipass.eq.3) llrd=llrc if(ipass.le.3) then apmask=0 iaptype=0 endif if(ipass .gt. 3) then llrd=llra if(.not.lapcqonly) then iaptype=naptypes(nQSOProgress,ipass-3) else iaptype=1 endif if(iaptype.ge.3 .and. (abs(f1-nfqso).gt.napwid .and. abs(f1-nftx).gt.napwid) ) cycle if(iaptype.eq.1 .or. iaptype.eq.2 ) then ! AP,???,??? apmask=0 apmask(1:29)=1 apmask(75:77)=1 llrd(75:77)=apmag*apsym(75:77) if(iaptype.eq.1) llrd(1:29)=apmag*mcq(1:29) if(iaptype.eq.2) llrd(1:29)=apmag*apsym(1:29) endif if(iaptype.eq.3) then ! mycall, dxcall, ??? apmask=0 apmask(1:56)=1 apmask(75:77)=1 llrd(1:56)=apmag*apsym(1:56) llrd(75:77)=apmag*apsym(75:77) endif if(iaptype.eq.4 .or. iaptype.eq.5 .or. iaptype.eq.6) then apmask=0 apmask(1:77)=1 ! mycall, hiscall, RRR|73|RR73 llrd(1:58)=apmag*apsym(1:58) if(iaptype.eq.4) llrd(59:77)=apmag*mrrr if(iaptype.eq.5) llrd(59:77)=apmag*m73 if(iaptype.eq.6) llrd(59:77)=apmag*mrr73 endif endif cw=0 call timer('bpd174_91 ',0) call bpdecode174_91(llrd,apmask,max_iterations,message77,cw,nharderrors, & niterations) call timer('bpd174_91 ',1) dmin=0.0 if(ndepth.eq.3 .and. nharderrors.lt.0) then ndeep=3 if(abs(nfqso-f1).le.napwid .or. abs(nftx-f1).le.napwid) then if((ipass.eq.3 .or. ipass.eq.4) .and. .not.nagain) then ndeep=3 else ndeep=4 endif endif if(nagain) ndeep=5 call timer('osd174_91 ',0) call osd174_91(llrd,apmask,ndeep,message77,cw,nharderrors,dmin) call timer('osd174_91 ',1) endif msg37=' ' xsnr=-99.0 if(nharderrors.lt.0 .or. nharderrors.gt.36) cycle if(count(cw.eq.0).eq.174) cycle !Reject the all-zero codeword write(c77,'(77i1)') message77 read(c77(72:74),'(b3)') n3 read(c77(75:77),'(b3)') i3 if(i3.gt.4 .or. (i3.eq.0.and.n3.gt.5)) then cycle endif call unpack77(c77,msg37,unpk77_success) if(.not.unpk77_success) then cycle endif nbadcrc=0 ! If we get this far: valid codeword, valid (i3,n3), nonquirky message. call genft8_174_91(msg37,i3,n3,msgsent37,msgbits,itone) if(lsubtract) call subtractft8(dd0,itone,f1,xdt) xsig=0.0 xnoi=0.0 do i=1,79 xsig=xsig+s8(itone(i),i)**2 ios=mod(itone(i)+4,7) xnoi=xnoi+s8(ios,i)**2 enddo xsnr=0.001 if(xnoi.gt.0 .and. xnoi.lt.xsig) xsnr=xsig/xnoi-1.0 xsnr=10.0*log10(xsnr)-27.0 ! need to reconcile signal normalization between this routine and the old ft8b_1 so ! that SNRs come out the same. xsnr2=db(xsig/xbase - 1.0) - 32.0 ! if(.not.nagain) xsnr=xsnr2 if(xsnr .lt. -24.0) xsnr=-24.0 return enddo return end subroutine ft8b_2 ! This currently resides in ft8b_1.f90 !subroutine normalizebmet(bmet,n) ! real bmet(n) ! ! bmetav=sum(bmet)/real(n) ! bmet2av=sum(bmet*bmet)/real(n) ! var=bmet2av-bmetav*bmetav ! if( var .gt. 0.0 ) then ! bmetsig=sqrt(var) ! else ! bmetsig=sqrt(bmet2av) ! endif ! bmet=bmet/bmetsig ! return !end subroutine normalizebmet