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https://github.com/saitohirga/WSJT-X.git
synced 2024-11-25 05:38:46 -05:00
Use 3rd order polynomial fit to estimate the noise baseline. The
polynomial fit is done over 400 Hz bandwidth for T/R periods longer than 15s, and over approx. 600 Hz (10 times the signal bandwidth) for T/R period of 15s.
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@ -618,6 +618,7 @@ set (wsjt_FSRCS
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lib/fst4/osd240_101.f90
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lib/fst4/osd240_74.f90
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lib/fst4/get_crc24.f90
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lib/fst4/fst4_baseline.f90
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)
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# temporary workaround for a gfortran v7.3 ICE on Fedora 27 64-bit
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48
lib/fst4/fst4_baseline.f90
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48
lib/fst4/fst4_baseline.f90
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@ -0,0 +1,48 @@
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subroutine fst4_baseline(s,np,ia,ib,npct,sbase)
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! Fit baseline to spectrum (for FST4)
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! Input: s(npts) Linear scale in power
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! Output: sbase(npts) Baseline
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implicit real*8 (a-h,o-z)
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real*4 s(np),sw(np)
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real*4 sbase(np)
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real*4 base
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real*8 x(1000),y(1000),a(5)
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data nseg/8/
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do i=ia,ib
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sw(i)=10.0*log10(s(i)) !Convert to dB scale
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enddo
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nterms=3
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nlen=(ib-ia+1)/nseg !Length of test segment
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i0=(ib-ia+1)/2 !Midpoint
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k=0
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do n=1,nseg !Loop over all segments
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ja=ia + (n-1)*nlen
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jb=ja+nlen-1
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call pctile(sw(ja),nlen,npct,base) !Find lowest npct of points
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do i=ja,jb
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if(sw(i).le.base) then
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if (k.lt.1000) k=k+1 !Save all "lower envelope" points
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x(k)=i-i0
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y(k)=sw(i)
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endif
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enddo
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enddo
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kz=k
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a=0.
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call polyfit(x,y,y,kz,nterms,0,a,chisqr) !Fit a low-order polynomial
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sbase=0.0
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do i=ia,ib
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t=i-i0
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sbase(i)=a(1)+t*(a(2)+t*(a(3))) + 0.2
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! write(51,3051) i,sw(i),sbase(i)
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!3051 format(i8,2f12.3)
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enddo
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sbase=10**(sbase/10.0)
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return
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end subroutine fst4_baseline
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@ -49,7 +49,7 @@ contains
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complex, allocatable :: cframe(:)
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complex, allocatable :: c_bigfft(:) !Complex waveform
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real llr(240),llrs(240,4)
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real candidates(200,4)
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real candidates(200,5)
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real bitmetrics(320,4)
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real s4(0:3,NN)
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real minsync
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@ -254,14 +254,19 @@ contains
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nhicoh=1
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nsyncoh=8
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fa=max(100,nint(nfqso+1.5*hmod*baud-ntol))
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fb=min(4800,nint(nfqso+1.5*hmod*baud+ntol))
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minsync=1.2
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if(iwspr.eq.1) then
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fa=1400.0
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fb=1600.0
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else
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fa=max(100,nint(nfqso+1.5*hmod*baud-ntol))
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fb=min(4800,nint(nfqso+1.5*hmod*baud+ntol))
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endif
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minsync=1.20
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if(ntrperiod.eq.15) minsync=1.15
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! Get first approximation of candidate frequencies
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call get_candidates_fst4(c_bigfft,nfft1,nsps,hmod,fs,fa,fb, &
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minsync,ncand,candidates,base)
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minsync,ncand,candidates)
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ndecodes=0
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decodes=' '
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@ -317,7 +322,7 @@ contains
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enddo
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ncand=ic
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xsnr=0.
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!write(*,*) 'ncand ',ncand
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do icand=1,ncand
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sync=candidates(icand,2)
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fc_synced=candidates(icand,3)
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@ -465,6 +470,7 @@ contains
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do i=1,NN
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xsig=xsig+s4(itone(i),i)
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enddo
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base=candidates(icand,5)
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arg=600.0*(xsig/base)-1.0
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if(arg.gt.0.0) then
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xsnr=10*log10(arg)-35.5-12.5*log10(nsps/8200.0)
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@ -645,14 +651,15 @@ contains
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end subroutine fst4_downsample
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subroutine get_candidates_fst4(c_bigfft,nfft1,nsps,hmod,fs,fa,fb, &
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minsync,ncand,candidates,base)
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minsync,ncand,candidates)
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complex c_bigfft(0:nfft1/2) !Full length FFT of raw data
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integer hmod !Modulation index (submode)
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integer im(1) !For maxloc
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real candidates(200,4) !Candidate list
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real candidates(200,5) !Candidate list
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real, allocatable :: s(:) !Low resolution power spectrum
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real, allocatable :: s2(:) !CCF of s() with 4 tones
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real, allocatable :: sbase(:) !noise baseline estimate
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real xdb(-3:3) !Model 4-tone CCF peaks
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real minsync
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data xdb/0.25,0.50,0.75,1.0,0.75,0.50,0.25/
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@ -668,17 +675,17 @@ contains
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signal_bw=4*(12000.0/nsps)*hmod
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analysis_bw=min(4800.0,fb)-max(100.0,fa)
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xnoise_bw=10.0*signal_bw !Is this a good compromise?
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if(analysis_bw.gt.xnoise_bw) then
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ina=ia
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inb=ib
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else
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fcenter=(fa+fb)/2.0 !If noise_bw > analysis_bw,
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fl = max(100.0,fcenter-xnoise_bw/2.)/df2 !we'll search over noise_bw
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if(xnoise_bw .lt. 400.0) xnoise_bw=400.0
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if(analysis_bw.gt.xnoise_bw) then !Estimate noise baseline over analysis bw
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ina=0.9*ia
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inb=min(int(1.1*ib),nfft1/2)
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else !Estimate noise baseline over noise bw
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fcenter=(fa+fb)/2.0
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fl = max(100.0,fcenter-xnoise_bw/2.)/df2
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fh = min(4800.0,fcenter+xnoise_bw/2.)/df2
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ina=nint(fl)
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inb=nint(fh)
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endif
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nnw=nint(48000.*nsps*2./fs)
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allocate (s(nnw))
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s=0. !Compute low-resolution power spectrum
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@ -692,12 +699,16 @@ contains
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ina=max(ina,1+3*hmod) !Don't run off the ends
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inb=min(inb,nnw-3*hmod)
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allocate (s2(nnw))
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allocate (sbase(nnw))
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s2=0.
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do i=ina,inb !Compute CCF of s() and 4 tones
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s2(i)=s(i-hmod*3) + s(i-hmod) +s(i+hmod) +s(i+hmod*3)
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enddo
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call pctile(s2(ina+hmod*3:inb-hmod*3),inb-ina+1-hmod*6,30,base)
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s2=s2/base !Normalize wrt noise level
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npct=30
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call fst4_baseline(s2,nnw,ina+hmod*3,inb-hmod*3,npct,sbase)
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if(any(sbase(ina:inb).le.0.0)) return
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s2(ina:inb)=s2(ina:inb)/sbase(ina:inb) !Normalize wrt noise level
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ncand=0
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candidates=0
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if(ia.lt.3) ia=3
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@ -717,12 +728,11 @@ contains
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s2(k)=max(0.,s2(k)-0.9*pval*xdb(i))
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endif
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enddo
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! s2(max(1,iploc-2*hmod*3):min(nnw,iploc+2*hmod*3))=0.0
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ncand=ncand+1
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candidates(ncand,1)=df2*iploc !Candidate frequency
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candidates(ncand,2)=pval !Rough estimate of SNR
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candidates(ncand,5)=sbase(iploc)
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enddo
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return
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end subroutine get_candidates_fst4
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