mirror of
https://github.com/saitohirga/WSJT-X.git
synced 2024-11-16 17:11:53 -05:00
dd1362b69a
Generic message packing and unpacking routines now understand antipode grid contest messages. These messages are now recognized as standard messages in message response processing and dealt with appropriately when contest mode is selected and applicable (currently FT8 and MSK144 only). git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@8062 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
272 lines
9.8 KiB
Fortran
272 lines
9.8 KiB
Fortran
program jt65sim
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! Generate simulated JT65 data for testing WSJT-X
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use wavhdr
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use packjt
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use options
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parameter (NMAX=54*12000) ! = 648,000
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parameter (NFFT=10*65536,NH=NFFT/2)
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type(hdr) h !Header for .wav file
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integer*2 iwave(NMAX) !Generated waveform
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integer*4 itone(126) !Channel symbols (values 0-65)
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integer dgen(12) !Twelve 6-bit data symbols
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integer sent(63) !RS(63,12) codeword
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real*4 xnoise(NMAX) !Generated random noise
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real*4 dat(NMAX) !Generated real data
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complex cdat(NMAX) !Generated complex waveform
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complex cspread(0:NFFT-1) !Complex amplitude for Rayleigh fading
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complex z
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real*8 f0,dt,twopi,phi,dphi,baud,fsample,freq,sps
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character msg*22,fname*11,csubmode*1,c,optarg*500,numbuf*32
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! character call1*5,call2*5
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logical :: display_help=.false.,seed_prngs=.true.
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type (option) :: long_options(8) = [ &
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option ('help',.false.,'h','Display this help message',''), &
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option ('sub-mode',.true.,'m','sub mode, default MODE=A','MODE'), &
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option ('num-sigs',.true.,'n','number of signals per file, default SIGNALS=10','SIGNALS'), &
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option ('doppler-spread',.true.,'d','Doppler spread, default SPREAD=0.0','SPREAD'), &
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option ('time-offset',.true.,'t','Time delta, default SECONDS=0.0','SECONDS'), &
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option ('num-files',.true.,'f','Number of files to generate, default FILES=1','FILES'), &
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option ('no-prng-seed',.false.,'p','Do not seed PRNGs (use for reproducible tests)',''), &
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option ('strength',.true.,'s','S/N in dB (2500Hz reference b/w), default SNR=0','SNR') ]
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integer nprc(126) !Sync pattern
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data nprc/1,0,0,1,1,0,0,0,1,1,1,1,1,1,0,1,0,1,0,0, &
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0,1,0,1,1,0,0,1,0,0,0,1,1,1,0,0,1,1,1,1, &
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0,1,1,0,1,1,1,1,0,0,0,1,1,0,1,0,1,0,1,1, &
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0,0,1,1,0,1,0,1,0,1,0,0,1,0,0,0,0,0,0,1, &
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1,0,0,0,0,0,0,0,1,1,0,1,0,0,1,0,1,1,0,1, &
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0,1,0,1,0,0,1,1,0,0,1,0,0,1,0,0,0,0,1,1, &
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1,1,1,1,1,1/
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! Default parameters:
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csubmode='A'
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mode65=1
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nsigs=10
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fspread=0.
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xdt=0.
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snrdb=0.
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nfiles=1
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do
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call getopt('hm:n:d:t:f:ps:',long_options,c,optarg,narglen,nstat,noffset,nremain,.true.)
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if( nstat .ne. 0 ) then
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exit
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end if
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select case (c)
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case ('h')
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display_help = .true.
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case ('m')
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read (optarg(:narglen), *) csubmode
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if(csubmode.eq.'A') mode65=1
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if(csubmode.eq.'B') mode65=2
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if(csubmode.eq.'C') mode65=4
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case ('n')
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read (optarg(:narglen), *,err=10) nsigs
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case ('d')
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read (optarg(:narglen), *,err=10) fspread
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case ('t')
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read (optarg(:narglen), *) numbuf
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if (numbuf(1:1) == '\') then
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read (numbuf(2:), *,err=10) xdt
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else
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read (numbuf, *,err=10) xdt
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end if
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case ('f')
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read (optarg(:narglen), *,err=10) nfiles
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case ('p')
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seed_prngs=.false.
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case ('s')
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read (optarg(:narglen), *) numbuf
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if (numbuf(1:1) == '\') then
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read (numbuf(2:), *,err=10) snrdb
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else
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read (numbuf, *,err=10) snrdb
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end if
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end select
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cycle
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10 display_help=.true.
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print *, 'Optional argument format error for option -', c
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end do
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if(display_help .or. nstat.lt.0 .or. nremain.ge.1) then
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print *, ''
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print *, 'Usage: jt65sim [OPTIONS]'
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print *, ''
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print *, ' Generate one or more simulated JT65 signals in .WAV file(s)'
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print *, ''
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print *, 'Example: jt65sim -m B -n 10 -d 0.2 -s \\-24.5 -t 0.0 -f 4'
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print *, ''
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print *, 'OPTIONS: NB Use \ (\\ on *nix shells) to escape -ve arguments'
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print *, ''
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do i = 1, size (long_options)
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call long_options(i) % print (6)
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end do
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go to 999
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endif
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if (seed_prngs) then
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call init_random_seed() ! seed Fortran RANDOM_NUMBER generator
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call sgran() ! see C rand generator (used in gran)
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end if
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rms=100.
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fsample=12000.d0 !Sample rate (Hz)
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dt=1.d0/fsample !Sample interval (s)
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twopi=8.d0*atan(1.d0)
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npts=54*12000 !Total samples in .wav file
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baud=11025.d0/4096.d0 !Keying rate
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sps=12000.d0/baud !Samples per symbol, at fsample=12000 Hz
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nsym=126 !Number of channel symbols
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h=default_header(12000,npts)
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dfsig=2000.0/nsigs !Freq spacing between sigs in file (Hz)
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do ifile=1,nfiles !Loop over requested number of files
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write(fname,1002) ifile !Output filename
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1002 format('000000_',i4.4)
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open(10,file=fname//'.wav',access='stream',status='unknown')
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xnoise=0.
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cdat=0.
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if(snrdb.lt.90) then
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do i=1,npts
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xnoise(i)=gran() !Generate gaussian noise
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enddo
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endif
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do isig=1,nsigs !Generate requested number of sigs
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if(mod(nsigs,2).eq.0) f0=1500.0 + dfsig*(isig-0.5-nsigs/2)
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if(mod(nsigs,2).eq.1) f0=1500.0 + dfsig*(isig-(nsigs+1)/2)
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xsnr=snrdb
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if(snrdb.eq.0.0) xsnr=-19 - isig
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if(csubmode.eq.'B' .and. snrdb.eq.0.0) xsnr=-21 - isig
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if(csubmode.eq.'C' .and. snrdb.eq.0.0) xsnr=-21 - isig
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!###
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! call1="K1ABC"
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! ic3=65+mod(isig-1,26)
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! ic2=65+mod((isig-1)/26,26)
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! ic1=65
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! call2="W9"//char(ic1)//char(ic2)//char(ic3)
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! write(msg,1010) call1,call2,nint(xsnr)
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!1010 format(a5,1x,a5,1x,i3.2)
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msg="K1ABC W9XYZ EN37"
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!###
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call packmsg(msg,dgen,itype,.false.) !Pack message into 12 six-bit bytes
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call rs_encode(dgen,sent) !Encode using RS(63,12)
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call interleave63(sent,1) !Interleave channel symbols
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call graycode65(sent,63,1) !Apply Gray code
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k=0
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do j=1,nsym !Insert sync and data into itone()
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if(nprc(j).eq.0) then
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k=k+1
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itone(j)=sent(k)+2
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else
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itone(j)=0
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endif
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enddo
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bandwidth_ratio=2500.0/6000.0
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sig=sqrt(2*bandwidth_ratio)*10.0**(0.05*xsnr)
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if(xsnr.gt.90.0) sig=1.0
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write(*,1020) ifile,isig,f0,csubmode,xsnr,xdt,fspread,msg
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1020 format(i4,i4,f10.3,2x,a1,2x,f5.1,f6.2,f5.1,1x,a22)
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phi=0.d0
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dphi=0.d0
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k=12000 + xdt*12000 !Start audio at t = xdt + 1.0 s
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isym0=-99
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do i=1,npts !Add this signal into cdat()
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isym=floor(i/sps)+1
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if(isym.gt.nsym) exit
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if(isym.ne.isym0) then
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freq=f0 + itone(isym)*baud*mode65
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dphi=twopi*freq*dt
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isym0=isym
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endif
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phi=phi + dphi
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if(phi.gt.twopi) phi=phi-twopi
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xphi=phi
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z=cmplx(cos(xphi),sin(xphi))
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k=k+1
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if(k.ge.1) cdat(k)=cdat(k) + sig*z
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enddo
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enddo
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if(fspread.ne.0) then !Apply specified Doppler spread
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df=12000.0/nfft
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twopi=8*atan(1.0)
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cspread(0)=1.0
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cspread(NH)=0.
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! The following options were added 3/15/2016 to make the half-power tone
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! widths equal to the requested Doppler spread. (Previously we effectively
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! used b=1.0 and Gaussian shape, which made the tones 1.665 times wider.)
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! b=2.0*sqrt(log(2.0)) !Gaussian (before 3/15/2016)
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! b=2.0 !Lorenzian 3/15 - 3/27
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b=6.0 !Lorenzian 3/28 onward
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do i=1,NH
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f=i*df
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x=b*f/fspread
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z=0.
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a=0.
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if(x.lt.3.0) then !Cutoff beyond x=3
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! a=sqrt(exp(-x*x)) !Gaussian
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a=sqrt(1.111/(1.0+x*x)-0.1) !Lorentzian
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call random_number(r1)
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phi1=twopi*r1
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z=a*cmplx(cos(phi1),sin(phi1))
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endif
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cspread(i)=z
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z=0.
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if(x.lt.50.0) then
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call random_number(r2)
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phi2=twopi*r2
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z=a*cmplx(cos(phi2),sin(phi2))
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endif
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cspread(NFFT-i)=z
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enddo
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do i=0,NFFT-1
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f=i*df
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if(i.gt.NH) f=(i-nfft)*df
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s=real(cspread(i))**2 + aimag(cspread(i))**2
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! write(13,3000) i,f,s,cspread(i)
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!3000 format(i5,f10.3,3f12.6)
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enddo
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! s=real(cspread(0))**2 + aimag(cspread(0))**2
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! write(13,3000) 1024,0.0,s,cspread(0)
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call four2a(cspread,NFFT,1,1,1) !Transform to time domain
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sum=0.
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do i=0,NFFT-1
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p=real(cspread(i))**2 + aimag(cspread(i))**2
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sum=sum+p
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enddo
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avep=sum/NFFT
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fac=sqrt(1.0/avep)
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cspread=fac*cspread !Normalize to constant avg power
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cdat=cspread(1:npts)*cdat !Apply Rayleigh fading
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! do i=0,NFFT-1
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! p=real(cspread(i))**2 + aimag(cspread(i))**2
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! write(14,3010) i,p,cspread(i)
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!3010 format(i8,3f12.6)
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! enddo
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endif
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dat=aimag(cdat) + xnoise !Add the generated noise
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fac=32767.0/nsigs
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if(snrdb.ge.90.0) iwave(1:npts)=nint(fac*dat(1:npts))
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if(snrdb.lt.90.0) iwave(1:npts)=nint(rms*dat(1:npts))
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write(10) h,iwave(1:npts) !Save the .wav file
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close(10)
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enddo
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999 end program jt65sim
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