js8call/.svn/pristine/60/607c5065108ba057df9b64e0c51bdfc8d8edf7e1.svn-base

program msksim

! Simulate characteristics of a potential "MSK10" mode using LDPC (168,84)
! code, OQPDK modulation, and 30 s T/R sequences.

! Reception and Demodulation algorithm:
!   1. Compute coarse spectrum; find fc1 = approx carrier freq
!   2. Mix from fc1 to 0; LPF at +/- 0.75*R
!   3. Square, FFT; find peaks near -R/2 and +R/2 to get fc2
!   4. Mix from fc2 to 0
!   5. Fit cb13 (central part of csync) to c -> lag, phase
!   6. Fit complex ploynomial for channel equalization
!   7. Get soft bits from equalized data

  parameter (KK=84)                     !Information bits (72 + CRC12)
  parameter (ND=168)                    !Data symbols: LDPC (168,84), r=1/2
  parameter (NS=65)                     !Sync symbols (2 x 26 + Barker 13)
  parameter (NR=3)                      !Ramp up/down
  parameter (NN=NR+NS+ND)               !Total symbols (236)
  parameter (NSPS=1152/72)              !Samples per MSK symbol (16)
  parameter (N2=2*NSPS)                 !Samples per OQPSK symbol (32)
  parameter (N13=13*N2)                 !Samples in central sync vector (416)
  parameter (NZ=NSPS*NN)                !Samples in baseband waveform (3776)
  parameter (NFFT1=4*NSPS,NH1=NFFT1/2)

  character*8 arg
  complex cbb(0:NZ-1)                   !Complex baseband waveform
  complex csync(0:NZ-1)                 !Sync symbols only, from cbb
  complex cb13(0:N13-1)                 !Barker 13 waveform
  complex c(0:NZ-1)                     !Complex waveform
  complex c0(0:NZ-1)                    !Complex waveform
  complex zz(NS+ND)                     !Complex symbol values (intermediate)
  complex z
  real xnoise(0:NZ-1)                   !Generated random noise
  real ynoise(0:NZ-1)                   !Generated random noise
  real rxdata(ND),llr(ND)               !Soft symbols
  real pp(2*NSPS)                       !Shaped pulse for OQPSK
  real a(5)                             !For twkfreq1
  real aa(20),bb(20)                    !Fitted polyco's
  integer id(NS+ND)                     !NRZ values (+/-1) for Sync and Data
  integer ierror(NS+ND)
  integer icw(NN)
  integer*1 msgbits(KK),decoded(KK),apmask(ND),cw(ND)
!  integer*1 codeword(ND)
  data msgbits/0,0,1,0,0,1,1,1,1,0,0,1,0,0,0,0,0,0,0,0,1,0,0,0,1,1,0,0,0,1, &
       1,1,1,0,1,1,1,1,1,1,1,0,0,1,0,0,1,1,0,1,0,1,1,1,0,1,1,0,1,1,         &
       1,1,0,1,0,1,1,0,0,0,0,0,1,0,0,0,0,0,1,0,1,0,1,0/

  nargs=iargc()
  if(nargs.ne.6) then
     print*,'Usage:   mskhfsim f0(Hz) delay(ms) fspread(Hz) maxn iters snr(dB)'
     print*,'Example: mskhfsim 0 0 0 5 10 -20'
     print*,'Set snr=0 to cycle through a range'
     go to 999
  endif
  call getarg(1,arg)
  read(arg,*) f0                         !Generated carrier frequency
  call getarg(2,arg)
  read(arg,*) delay                      !Delta_t (ms) for Watterson model
  call getarg(3,arg)
  read(arg,*) fspread                    !Fspread (Hz) for Watterson model
  call getarg(4,arg)
  read(arg,*) maxn                       !Max nterms for polyfit
  call getarg(5,arg)
  read(arg,*) iters                      !Iterations at each SNR
  call getarg(6,arg)
  read(arg,*) snrdb                      !Specified SNR_2500
  
  twopi=8.0*atan(1.0)
  fs=12000.0/72.0                        !Sample rate = 166.6666667 Hz
  dt=1.0/fs                              !Sample interval (s)
  tt=NSPS*dt                             !Duration of "itone" symbols (s)
  ts=2*NSPS*dt                           !Duration of OQPSK symbols (s)
  baud=1.0/tt                            !Keying rate for "itone" symbols (baud)
  txt=NZ*dt                              !Transmission length (s)
  bandwidth_ratio=2500.0/(fs/2.0)
  write(*,1000) f0,delay,fspread,maxn,iters,baud,3*baud,txt
1000 format('f0:',f5.1,'  Delay:',f4.1,'  fSpread:',f5.2,'  maxn:',i3,   &
          '  Iters:',i6/'Baud:',f7.3,'  BW:',f5.1,'  TxT:',f5.1,f5.2/)
  write(*,1004)
1004 format(/'  SNR     err    ber    fer   fsigma'/37('-'))

  do i=1,N2                              !Half-sine pulse shape
     pp(i)=sin(0.5*(i-1)*twopi/(2*NSPS))
  enddo
  
  call genmskhf(msgbits,id,icw,cbb,csync)!Generate baseband waveform and csync
  cb13=csync(1680:2095)                  !Copy the Barker 13 waveform
  a=0.
  a(1)=f0
  call twkfreq1(cbb,NZ,fs,a,cbb)         !Mix to specified frequency

  isna=-10
  isnb=-30
  if(snrdb.ne.0.0) then
     isna=nint(snrdb)
     isnb=isna
  endif
  do isnr=isna,isnb,-1                   !Loop over SNR range
     snrdb=isnr
     sig=sqrt(bandwidth_ratio) * 10.0**(0.05*snrdb)
     if(snrdb.gt.90.0) sig=1.0
     nhard=0
     nhardsync=0
     nfe=0
     sqf=0.
     do iter=1,iters                     !Loop over requested iterations
        c=cbb
        if(delay.ne.0.0 .or. fspread.ne.0.0) then
           call watterson(c,NZ,fs,delay,fspread)
        endif
        c=sig*c                          !Scale to requested SNR
        if(snrdb.lt.90) then
           do i=0,NZ-1                   !Generate gaussian noise
              xnoise(i)=gran()
              ynoise(i)=gran()
           enddo
           c=c + cmplx(xnoise,ynoise)    !Add AWGN noise
        endif

        call getfc1(c,fc1)               !First approx for freq
        call getfc2(c,csync,fc1,fc2,fc3) !Refined freq
        sqf=sqf + (fc1+fc2-f0)**2
        
!NB: Measured performance is about equally good using fc2 or fc3 here:
        a(1)=-(fc1+fc2)
        a(2:5)=0.
        call twkfreq1(c,NZ,fs,a,c)       !Mix c down by fc1+fc2

! The following may not be necessary?
!        z=sum(c(1680:2095)*cb13)/208.0     !Get phase from Barker 13 vector
!        z0=z/abs(z)
!        c=c*conjg(z0)

!---------------------------------------------------------------- DT
! Not presently used:
        amax=0.
        jpk=0
        do j=-20*NSPS,20*NSPS            !Get jpk
           z=sum(c(1680+j:2095+j)*cb13)/208.0
           if(abs(z).gt.amax) then
              amax=abs(z)
              jpk=j
           endif
        enddo
        xdt=jpk/fs

        nterms=maxn
        c0=c
        do itry=1,10
           idf=itry/2
           if(mod(itry,2).eq.0) idf=-idf
           nhard0=0
           nhardsync0=0
           ifer=1
           a(1)=idf*0.01
           a(2:5)=0.
           call twkfreq1(c0,NZ,fs,a,c)       !Mix c0 into c
           call cpolyfit(c,pp,id,maxn,aa,bb,zz,nhs)
           call msksoftsym(zz,aa,bb,id,nterms,ierror,rxdata,nhard0,nhardsync0)
           if(nhardsync0.gt.12) cycle
           rxav=sum(rxdata)/ND
           rx2av=sum(rxdata*rxdata)/ND
           rxsig=sqrt(rx2av-rxav*rxav)
           rxdata=rxdata/rxsig
           ss=0.84
           llr=2.0*rxdata/(ss*ss)
           apmask=0
           max_iterations=40
           ifer=0
           call bpdecode168(llr,apmask,max_iterations,decoded,niterations,cw)
           nbadcrc=0
           if(niterations.ge.0) call chkcrc12(decoded,nbadcrc)
           if(niterations.lt.0 .or. count(msgbits.ne.decoded).gt.0 .or.        &
                nbadcrc.ne.0) ifer=1
!           if(ifer.eq.0) write(67,1301) snrdb,itry,idf,niterations,    &
!                nhardsync0,nhard0
!1301       format(f6.1,5i6)
           if(ifer.eq.0) exit
        enddo                                !Freq dither loop
        nhard=nhard+nhard0
        nhardsync=nharsdync+nhardsync0
        nfe=nfe+ifer
     enddo

     fsigma=sqrt(sqf/iters)
     ber=float(nhard)/((NS+ND)*iters)
     fer=float(nfe)/iters
     write(*,1050)  snrdb,nhard,ber,fer,fsigma
!     write(60,1050)  snrdb,nhard,ber,fer,fsigma
1050 format(f6.1,i7,f8.4,f7.3,f8.2)
  enddo

999 end program msksim
Initial Commit 2018-02-08 21:28:33 -05:00			`program msksim`

			`! Simulate characteristics of a potential "MSK10" mode using LDPC (168,84)`
			`! code, OQPDK modulation, and 30 s T/R sequences.`

			`! Reception and Demodulation algorithm:`
			`! 1. Compute coarse spectrum; find fc1 = approx carrier freq`
			`! 2. Mix from fc1 to 0; LPF at +/- 0.75*R`
			`! 3. Square, FFT; find peaks near -R/2 and +R/2 to get fc2`
			`! 4. Mix from fc2 to 0`
			`! 5. Fit cb13 (central part of csync) to c -> lag, phase`
			`! 6. Fit complex ploynomial for channel equalization`
			`! 7. Get soft bits from equalized data`

			`parameter (KK=84) !Information bits (72 + CRC12)`
			`parameter (ND=168) !Data symbols: LDPC (168,84), r=1/2`
			`parameter (NS=65) !Sync symbols (2 x 26 + Barker 13)`
			`parameter (NR=3) !Ramp up/down`
			`parameter (NN=NR+NS+ND) !Total symbols (236)`
			`parameter (NSPS=1152/72) !Samples per MSK symbol (16)`
			`parameter (N2=2*NSPS) !Samples per OQPSK symbol (32)`
			`parameter (N13=13*N2) !Samples in central sync vector (416)`
			`parameter (NZ=NSPS*NN) !Samples in baseband waveform (3776)`
			`parameter (NFFT1=4*NSPS,NH1=NFFT1/2)`

			`character*8 arg`
			`complex cbb(0:NZ-1) !Complex baseband waveform`
			`complex csync(0:NZ-1) !Sync symbols only, from cbb`
			`complex cb13(0:N13-1) !Barker 13 waveform`
			`complex c(0:NZ-1) !Complex waveform`
			`complex c0(0:NZ-1) !Complex waveform`
			`complex zz(NS+ND) !Complex symbol values (intermediate)`
			`complex z`
			`real xnoise(0:NZ-1) !Generated random noise`
			`real ynoise(0:NZ-1) !Generated random noise`
			`real rxdata(ND),llr(ND) !Soft symbols`
			`real pp(2*NSPS) !Shaped pulse for OQPSK`
			`real a(5) !For twkfreq1`
			`real aa(20),bb(20) !Fitted polyco's`
			`integer id(NS+ND) !NRZ values (+/-1) for Sync and Data`
			`integer ierror(NS+ND)`
			`integer icw(NN)`
			`integer*1 msgbits(KK),decoded(KK),apmask(ND),cw(ND)`
			`! integer*1 codeword(ND)`
			`data msgbits/0,0,1,0,0,1,1,1,1,0,0,1,0,0,0,0,0,0,0,0,1,0,0,0,1,1,0,0,0,1, &`
			`1,1,1,0,1,1,1,1,1,1,1,0,0,1,0,0,1,1,0,1,0,1,1,1,0,1,1,0,1,1, &`
			`1,1,0,1,0,1,1,0,0,0,0,0,1,0,0,0,0,0,1,0,1,0,1,0/`

			`nargs=iargc()`
			`if(nargs.ne.6) then`
			`print*,'Usage: mskhfsim f0(Hz) delay(ms) fspread(Hz) maxn iters snr(dB)'`
			`print*,'Example: mskhfsim 0 0 0 5 10 -20'`
			`print*,'Set snr=0 to cycle through a range'`
			`go to 999`
			`endif`
			`call getarg(1,arg)`
			`read(arg,*) f0 !Generated carrier frequency`
			`call getarg(2,arg)`
			`read(arg,*) delay !Delta_t (ms) for Watterson model`
			`call getarg(3,arg)`
			`read(arg,*) fspread !Fspread (Hz) for Watterson model`
			`call getarg(4,arg)`
			`read(arg,*) maxn !Max nterms for polyfit`
			`call getarg(5,arg)`
			`read(arg,*) iters !Iterations at each SNR`
			`call getarg(6,arg)`
			`read(arg,*) snrdb !Specified SNR_2500`

			`twopi=8.0*atan(1.0)`
			`fs=12000.0/72.0 !Sample rate = 166.6666667 Hz`
			`dt=1.0/fs !Sample interval (s)`
			`tt=NSPS*dt !Duration of "itone" symbols (s)`
			`ts=2NSPSdt !Duration of OQPSK symbols (s)`
			`baud=1.0/tt !Keying rate for "itone" symbols (baud)`
			`txt=NZ*dt !Transmission length (s)`
			`bandwidth_ratio=2500.0/(fs/2.0)`
			`write(,1000) f0,delay,fspread,maxn,iters,baud,3baud,txt`
			`1000 format('f0:',f5.1,' Delay:',f4.1,' fSpread:',f5.2,' maxn:',i3, &`
			`' Iters:',i6/'Baud:',f7.3,' BW:',f5.1,' TxT:',f5.1,f5.2/)`
			`write(*,1004)`
			`1004 format(/' SNR err ber fer fsigma'/37('-'))`

			`do i=1,N2 !Half-sine pulse shape`
			`pp(i)=sin(0.5(i-1)twopi/(2*NSPS))`
			`enddo`

			`call genmskhf(msgbits,id,icw,cbb,csync)!Generate baseband waveform and csync`
			`cb13=csync(1680:2095) !Copy the Barker 13 waveform`
			`a=0.`
			`a(1)=f0`
			`call twkfreq1(cbb,NZ,fs,a,cbb) !Mix to specified frequency`

			`isna=-10`
			`isnb=-30`
			`if(snrdb.ne.0.0) then`
			`isna=nint(snrdb)`
			`isnb=isna`
			`endif`
			`do isnr=isna,isnb,-1 !Loop over SNR range`
			`snrdb=isnr`
			`sig=sqrt(bandwidth_ratio) * 10.0*(0.05snrdb)`
			`if(snrdb.gt.90.0) sig=1.0`
			`nhard=0`
			`nhardsync=0`
			`nfe=0`
			`sqf=0.`
			`do iter=1,iters !Loop over requested iterations`
			`c=cbb`
			`if(delay.ne.0.0 .or. fspread.ne.0.0) then`
			`call watterson(c,NZ,fs,delay,fspread)`
			`endif`
			`c=sig*c !Scale to requested SNR`
			`if(snrdb.lt.90) then`
			`do i=0,NZ-1 !Generate gaussian noise`
			`xnoise(i)=gran()`
			`ynoise(i)=gran()`
			`enddo`
			`c=c + cmplx(xnoise,ynoise) !Add AWGN noise`
			`endif`

			`call getfc1(c,fc1) !First approx for freq`
			`call getfc2(c,csync,fc1,fc2,fc3) !Refined freq`
			`sqf=sqf + (fc1+fc2-f0)**2`

			`!NB: Measured performance is about equally good using fc2 or fc3 here:`
			`a(1)=-(fc1+fc2)`
			`a(2:5)=0.`
			`call twkfreq1(c,NZ,fs,a,c) !Mix c down by fc1+fc2`

			`! The following may not be necessary?`
			`! z=sum(c(1680:2095)*cb13)/208.0 !Get phase from Barker 13 vector`
			`! z0=z/abs(z)`
			`! c=c*conjg(z0)`

			`!---------------------------------------------------------------- DT`
			`! Not presently used:`
			`amax=0.`
			`jpk=0`
			`do j=-20NSPS,20NSPS !Get jpk`
			`z=sum(c(1680+j:2095+j)*cb13)/208.0`
			`if(abs(z).gt.amax) then`
			`amax=abs(z)`
			`jpk=j`
			`endif`
			`enddo`
			`xdt=jpk/fs`

			`nterms=maxn`
			`c0=c`
			`do itry=1,10`
			`idf=itry/2`
			`if(mod(itry,2).eq.0) idf=-idf`
			`nhard0=0`
			`nhardsync0=0`
			`ifer=1`
			`a(1)=idf*0.01`
			`a(2:5)=0.`
			`call twkfreq1(c0,NZ,fs,a,c) !Mix c0 into c`
			`call cpolyfit(c,pp,id,maxn,aa,bb,zz,nhs)`
			`call msksoftsym(zz,aa,bb,id,nterms,ierror,rxdata,nhard0,nhardsync0)`
			`if(nhardsync0.gt.12) cycle`
			`rxav=sum(rxdata)/ND`
			`rx2av=sum(rxdata*rxdata)/ND`
			`rxsig=sqrt(rx2av-rxav*rxav)`
			`rxdata=rxdata/rxsig`
			`ss=0.84`
			`llr=2.0rxdata/(ssss)`
			`apmask=0`
			`max_iterations=40`
			`ifer=0`
			`call bpdecode168(llr,apmask,max_iterations,decoded,niterations,cw)`
			`nbadcrc=0`
			`if(niterations.ge.0) call chkcrc12(decoded,nbadcrc)`
			`if(niterations.lt.0 .or. count(msgbits.ne.decoded).gt.0 .or. &`
			`nbadcrc.ne.0) ifer=1`
			`! if(ifer.eq.0) write(67,1301) snrdb,itry,idf,niterations, &`
			`! nhardsync0,nhard0`
			`!1301 format(f6.1,5i6)`
			`if(ifer.eq.0) exit`
			`enddo !Freq dither loop`
			`nhard=nhard+nhard0`
			`nhardsync=nharsdync+nhardsync0`
			`nfe=nfe+ifer`
			`enddo`

			`fsigma=sqrt(sqf/iters)`
			`ber=float(nhard)/((NS+ND)*iters)`
			`fer=float(nfe)/iters`
			`write(*,1050) snrdb,nhard,ber,fer,fsigma`
			`! write(60,1050) snrdb,nhard,ber,fer,fsigma`
			`1050 format(f6.1,i7,f8.4,f7.3,f8.2)`
			`enddo`

			`999 end program msksim`