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https://github.com/saitohirga/WSJT-X.git
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2131414791
Use a header format for polynomial coefficients that includes the valid X range in scaled terms and a count of the number of coefficients. Use double precision consistently for polynomial coefficients. This includes formatting with sufficient DPs when writing to files. Many changes to the equalization plots, more to come. Add error handling for reading coefficient, plot and filter files. This includes being backward compatible for old format refspec.dat files with no header. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7578 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
155 lines
4.4 KiB
Fortran
155 lines
4.4 KiB
Fortran
subroutine refspectrum(id2,bclear,brefspec,buseref,fname)
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! Input:
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! id2 i*2 Raw 16-bit integer data, 12000 Hz sample rate
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! brefspec logical True when accumulating a reference spectrum
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parameter (NFFT=6912,NH=NFFT/2,NPOLYLOW=400,NPOLYHIGH=2600)
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integer*2 id2(NFFT)
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logical*1 bclear,brefspec,buseref,blastuse
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real x0(0:NH-1) !Input samples
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real x1(0:NH-1) !Output samples (delayed by one block)
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real x0s(0:NH-1) !Saved upper half of input samples
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real x1s(0:NH-1) !Saved upper half of output samples
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real x(0:NFFT-1) !Work array
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real*4 w(0:NFFT-1) !Window function
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real*4 s(0:NH) !Average spectrum
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real*4 fil(0:NH)
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real*8 xfit(1500),yfit(1500),sigmay(1500),a(5),chisqr !Polyfit arrays
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logical first
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complex cx(0:NH) !Complex frequency-domain work array
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character*(*) fname
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common/spectra/syellow(6827),ref(0:NH),filter(0:NH)
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equivalence(x,cx)
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data first/.true./,blastuse/.false./
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save
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if(first) then
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pi=4.0*atan(1.0)
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do i=0,NFFT-1
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ww=sin(i*pi/NFFT)
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w(i)=ww*ww/NFFT
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enddo
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nsave=0
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s=0.0
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filter=1.0
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x0s=0.
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x1s=0.
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first=.false.
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endif
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if(bclear) s=0.
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if(brefspec) then
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x(0:NH-1)=0.001*id2(1:NH)
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x(NH:NFFT-1)=0.0
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call four2a(x,NFFT,1,-1,0) !r2c FFT
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do i=1,NH
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s(i)=s(i) + real(cx(i))**2 + aimag(cx(i))**2
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enddo
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nsave=nsave+1
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fac0=0.9
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if(mod(nsave,4).eq.0) then
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df=12000.0/NFFT
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ia=nint(1000.0/df)
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ib=nint(2000.0/df)
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avemid=sum(s(ia:ib))/(ib-ia+1)
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do i=0,NH
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fil(i)=0.
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if(s(i).gt.0.0) then
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fil(i)=sqrt(avemid/s(i))
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endif
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enddo
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! Default range is 240 - 4000 Hz. For narrower filters, use frequencies
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! at which gain is -20 dB relative to 1500 Hz.
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ia=nint(240.0/df)
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ib=nint(4000.0/df)
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i0=nint(1500.0/df)
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do i=i0,ia,-1
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if(s(i)/s(i0).lt.0.01) exit
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enddo
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ia=i
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do i=i0,ib,1
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if(s(i)/s(i0).lt.0.01) exit
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enddo
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ib=i
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fac=fac0
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do i=ia,1,-1
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fac=fac*fac0
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fil(i)=fac*fil(i)
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enddo
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fac=fac0
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do i=ib,NH
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fac=fac*fac0
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fil(i)=fac*fil(i)
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enddo
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do iter=1,100 !### ??? ###
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call smo121(fil,NH)
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enddo
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do i=0,NH
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filter(i)=-60.0
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if(s(i).gt.0.0) filter(i)=20.0*log10(fil(i))
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enddo
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il=nint(NPOLYLOW/df)
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ih=nint(NPOLYHIGH/df)
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nfit=ih-il+1
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mode=0
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nterms=5
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do i=1,nfit
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xfit(i)=((i+il-1)*df-1500.0)/1000.0
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yfit(i)=fil(i+il-1)
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sigmay(i)=1.0
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enddo
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call polyfit(xfit,yfit,sigmay,nfit,nterms,mode,a,chisqr)
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open(16,file=fname,status='unknown')
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write(16,1003) NPOLYLOW,NPOLYHIGH,nterms,a
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1003 format(3i5,5e25.16)
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do i=1,NH
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freq=i*df
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ref(i)=db(s(i)/avemid)
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write(16,1005) freq,s(i),ref(i),fil(i),filter(i)
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1005 format(f10.3,e12.3,f12.6,e12.3,f12.6)
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enddo
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close(16)
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endif
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return
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endif
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if(buseref) then
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if(blastuse.neqv.buseref) then !just enabled so read filter
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fil=1.0
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open(16,file=fname,status='old',err=110)
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read(16,1003,err=20,end=100) ndummy,ndummy,nterms,a
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goto 30
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20 rewind(16) !allow for old style refspec.dat with no header
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30 do i=1,NH
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read(16,1005,err=100,end=100) freq,s(i),ref(i),fil(i),filter(i)
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enddo
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100 close(16)
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110 continue
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endif
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x0=id2(1:NH)
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x(0:NH-1)=x0s !Previous 2nd half to new 1st half
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x(NH:NFFT-1)=x0 !New 2nd half
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x0s=x0 !Save the new 2nd half
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x=w*x !Apply window
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call four2a(x,NFFT,1,-1,0) !r2c FFT (to frequency domain)
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cx=fil*cx
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call four2a(cx,NFFT,1,1,-1) !c2r FFT (back to time domain)
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x1=x1s + x(0:NH-1) !Add previous segment's 2nd half
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id2(1:NH)=nint(x1)
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x1s=x(NH:NFFT-1) !Save the new 2nd half
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endif
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blastuse=buseref
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return
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end subroutine refspectrum
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