!---------------------------------------------------- End Module Audio1 !---------------------------------------------------- spec subroutine spec(brightness,contrast,logmap,ngain,nspeed,a) ! Called by SpecJT in its TopLevel Python code. ! Probably should use the "!f2py intent(...)" structure here. ! Input: integer brightness,contrast !Display parameters integer ngain !Digital gain for input audio integer nspeed !Scrolling speed index ! Output: integer*2 a(225000) !Pixel values for 750 x 300 array real psa(750) !Grand average spectrum real ref(750) !Ref spect: smoothed ave of lower half real birdie(750) !Spec (with birdies) for plot, in dB real variance(750) !Variance in each spectral channel real a0(225000) !Save the last 300 spectra integer*2 idat(11025) !Sound data, read from file integer nstep(5) integer b0,c0 real x(4096) !Data for FFT complex c(0:2048) !Complex spectrum real ss(1024) !Bottom half of power spectrum logical first include 'gcom1.f90' include 'gcom2.f90' include 'gcom3.f90' include 'gcom4.f90' data jz/0/ !Number of spectral lines available data nstep/15,10,5,2,1/ !Integration limits data first/.true./ equivalence (x,c) save if(first) then call zero(ss,nq) istep=2205 nfft=4096 nq=nfft/4 df=11025.0/nfft fac=2.0/10000. nsum=0 iread=0 cversion='5.5.0 ' first=.false. b0=-999 c0=-999 logmap0=-999 nspeed0=-999 nx=0 ncall=0 jza=0 rms=0. endif nmode=1 if(mode(1:4).eq.'JT65') nmode=2 if(mode.eq.'Echo') nmode=3 if(mode.eq.'JT6M') nmode=4 nlines=0 newdat=0 npts=iwrite-iread if(ndiskdat.eq.1) then npts=jzc/2048 npts=2048*npts kread=0 if(nspeed.ge.6) then call hscroll(a,nx) nx=0 endif endif if(npts.lt.0) npts=npts+nmax if(npts.lt.nfft) go to 900 !Not enough data available 10 continue if(ndiskdat.eq.1) then ! Data read from disk k=kread do i=1,nfft k=k+1 x(i)=0.4*d2c(k) enddo kread=kread+istep !Update pointer else ! Real-time data dgain=2.0*10.0**(0.005*ngain) k=iread do i=1,nfft k=k+1 if(k.gt.nmax) k=k-nmax x(i)=0.5*dgain*y1(k) enddo iread=iread+istep !Update pointer if(iread.gt.nmax) iread=iread-nmax endif sum=0. !Get ave, rms of data do i=1,nfft sum=sum+x(i) enddo ave=sum/nfft sq=0. do i=1,nfft d=x(i)-ave sq=sq+d*d x(i)=fac*d enddo rms1=sqrt(sq/nfft) if(rms.eq.0) rms=rms1 rms=0.25*rms1 + 0.75*rms if(ndiskdat.eq.0) then level=0 !Compute S-meter level if(rms.gt.0.0) then !Scale 0-100, steps = 0.4 dB dB=20.0*log10(rms/800.0) level=50 + 2.5*dB if(level.lt.0) level=0 if(level.gt.100) level=100 endif endif if(nspeed.ge.6) then call horizspec(x,brightness,contrast,a) ncall=Mod(ncall+1,5) if(ncall.eq.1 .or. nspeed.eq.7) newdat=1 if(ndiskdat.eq.1) then npts=jzc-kread else npts=iwrite-iread if(npts.lt.0) npts=npts+nmax endif if(npts.ge.4096) go to 10 go to 900 endif call xfft(x,nfft) do i=1,nq !Accumulate power spectrum ss(i)=ss(i) + real(c(i))**2 + imag(c(i))**2 enddo nsum=nsum+1 if(nsum.ge.nstep(nspeed)) then !Integrate for specified time nlines=nlines+1 do i=225000,751,-1 !Move spectra up one row a0(i)=a0(i-750) ! (will be "down" on display) enddo if(ndiskdat.eq.1 .and. nlines.eq.1) then do i=1,750 a0(i)=255 enddo do i=225000,751,-1 a0(i)=a0(i-750) enddo endif if(nflat.gt.0) call flat2(ss,1024,nsum) do i=1,750 !Insert new data in top row j=i+182 ! ?? was 186 ?? a0(i)=5*ss(j)/nsum xdb=-40. if(a0(i).gt.0.) xdb=10*log10(a0(i)) enddo nsum=0 newdat=1 !Flag for new spectrum available call zero(ss,nq) !Zero the accumulating array if(jz.lt.300) jz=jz+1 endif if(ndiskdat.eq.1) then npts=jzc-kread else npts=iwrite-iread if(npts.lt.0) npts=npts+nmax endif if(npts.ge.4096) go to 10 ! Compute pixel values iz=750 logmap=0 if(brightness.ne.b0 .or. contrast.ne.c0 .or. logmap.ne.logmap0 .or. & nspeed.ne.nspeed0 .or. nlines.gt.1) then iz=225000 gain=40*sqrt(nstep(nspeed)/5.0) * 5.0**(0.01*contrast) gamma=1.3 + 0.01*contrast offset=(brightness+64.0)/2 b0=brightness c0=contrast logmap0=logmap nspeed0=nspeed endif ! print*,brightness,contrast,logmap,gain,gamma,offset do i=1,iz n=0 if(a0(i).gt.0.0 .and. logmap.eq.1) n=gain*log10(0.001*a0(i)) + offset + 20 if(a0(i).gt.0.0 .and. logmap.eq.0) n=(0.01*a0(i))**gamma + offset n=min(252,max(0,n)) a(i)=n enddo 900 continue return end subroutine spec