WSJT-X/lib/mskber.f90
Joe Taylor f98c5070c5 More code cleanup of test program mskber.f90.
git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6487 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-02-23 15:48:03 +00:00

147 lines
4.6 KiB
Fortran

program mskber
! Generate an MSK waveform, pass it through an AWGN channel, apply coherent
! MSK receiver, and count number of errors at each Eb/No.
parameter (MAXSYM=1000*1000)
parameter (NSPS=5) !Samples per symbol
real ct(-NSPS:NSPS*MAXSYM-1) !cos(pi*t/2T)
real st(-NSPS:NSPS*MAXSYM-1) !sin(pi*t/2T)
real r(0:MAXSYM-1) !Random numbers to set test bits
real xsym(0:MAXSYM-1) !Soft Rx symbols
complex xt(-NSPS:NSPS*MAXSYM-1) !Complex baseband Tx waveform
complex nt(-NSPS:NSPS*MAXSYM-1) !Generated AWGN channel noise
complex yt(-NSPS:NSPS*MAXSYM-1) !Received signal, yt = xt + fac*nt
complex cwave(-NSPS:NSPS*MAXSYM-1) !Audio waveform, Tx real part
complex z
integer sym0(0:MAXSYM-1) !Generated test bits
integer sym(0:MAXSYM-1) !Hard-copy received bits
integer sym1(0:7)
character*12 arg
data sym1/1,1,0,0,0,1,1,1/
nargs=iargc()
if(nargs.ne.2) then
print*,'Usage: mskber nsym EbNo'
go to 999
endif
call getarg(1,arg)
read(arg,*) nsym
call getarg(2,arg)
read(arg,*) EbNo
pi=4.0*atan(1.0)
do i=-NSPS,NSPS*nsym-1 !Define ct, st arrays
t=i*pi/(2.0*NSPS)
ct(i)=cos(t)
st(i)=sin(t)
enddo
fac=1.0/sqrt(float(NSPS))
do iEbNo=0,10 !Loop over a range of Eb/No
sym0=0
call random_number(r)
where(r(0:nsym-1).gt.0.5) sym0(0:nsym-1)=1 !Generate random data bits
if(nsym.eq.8) sym0(0:nsym-1)=sym1
call mskmod(sym0,nsym,NSPS,ct,st,xt,cwave) !Generate Tx waveform
do i=-NSPS,NSPS*nsym-1 !Generate Gaussian noise
xx=0.707*gran()
yy=0.707*gran()
nt(i)=cmplx(xx,yy)
enddo
fac_noise=10.0**(-iEbNo/20.0)
if(EbNo.ne.0.0) fac_noise=10.0**(-EbNo/20.0)
yt=xt + fac_noise*nt !Rx signal, with noise
call mskdemod(yt,nsym,NSPS,ct,st,xsym) !MSK demodulator
sym=0
where(xsym.gt.0.0) sym=1
if(nsym.le.160 .and. EbNo.ne.0.0) then
write(*,1012) sym0(0:nsym-1)
if(nsym.gt.50) write(*,1012)
write(*,1012) sym(0:nsym-1)
1012 format(50i1)
do i=-nsps,nsps*nsym-1
phi=i*2.0*pi*1500/12000.0
z=cwave(i)*cmplx(cos(phi),sin(phi)) !Mix back to baseband
write(51,1014) float(i)/nsps,xt(i),abs(xt(i)),cwave(i),z
1014 format(8f8.4)
enddo
endif
! Count the hard errors
nerr=count(sym(0:nsym-1).ne.sym0(0:nsym-1))
thber=0.5*erfc(10.0**(iEbNo/20.0))
xEbNo=iEbNo
if(EbNo.ne.0.0) xEbNo=EbNo
write(*,1000) xEbNo,thber,float(nerr)/nsym
1000 format(f6.1,2f10.6)
if(EbNo.ne.0.0) exit
enddo
999 end program mskber
subroutine mskmod(sym,nsym,nsps,ct,st,xt,cwave)
! Generate MSK Tx waveform at baseband.
integer sym(0:nsym-1) !Hard-copy received bits
complex xt(-nsps:nsps*nsym-1) !Complex baseband Tx waveform
complex cwave(-nsps:nsps*nsym-1) !Audio waveform, fc=1500 Hz.
real ct(-nsps:nsps*nsym-1) !cos(pi*t/2T)
real st(-nsps:nsps*nsym-1) !sin(pi*t/2T)
real ai(-nsps:nsps*nsym-1) !Rectangular pulses for even symbols
real aq(-nsps:nsps*nsym-1) !Rectangular pulses for odd symbols
ai=0.
aq=0.
fac=1.0/sqrt(float(nsps))
do j=0,nsym-1,2
ia=(j-1)*nsps
ib=ia+2*nsps-1
ai(ia:ib)=2*sym(j)-1 !Even bits as rectangular pulses
aq(ia+nsps:ib+nsps)=2*sym(j+1)-1 !Odd bits as rectangular pulses
enddo
xt=fac*cmplx(ai*ct,aq*st) !Baseband Tx waveform
twopi=8.0*atan(1.0)
do i=-nsps,nsps*nsym-1
phi=i*twopi*1500/12000.0
cwave(i)=xt(i)*cmplx(cos(phi),-sin(phi))
enddo
return
end subroutine mskmod
subroutine mskdemod(yt,nsym,nsps,ct,st,xsym)
! MSK demodulator
! Rx phase must be known and stable; symbol sync must be established.
complex yt(-nsps:nsps*nsym-1) !Received signal
real ct(-nsps:nsps*nsym-1) !cos(pi*t/2T)
real st(-nsps:nsps*nsym-1) !sin(pi*t/2T)
real xe(-nsps:nsps*nsym-1) !Temp array for received even symbols
real xo(-nsps:nsps*nsym-1) !Temp array for received odd symbols
real xsym(0:nsym-1) !Soft Rx symbols
iz=nsps*(nsym+1)
xe(-nsps:nsps*nsym-1)=real(yt)*ct !Apply matched filters
xo(-nsps:nsps*nsym-1)=aimag(yt)*st
do j=0,nsym-1,2
ia=(j-1)*nsps
ib=ia+2*nsps-1
xsym(j)=sum(xe(ia:ib)) !Integrate over 2 symbol lengths
xsym(j+1)=sum(xo(ia+nsps:ib+nsps))
enddo
return
end subroutine mskdemod