js8call/.svn/pristine/0c/0c2e2d47cd138a0640866da9ed977c337a03c542.svn-base

subroutine analytic(d,npts,nfft,c,pc,beq)

! Convert real data to analytic signal

  parameter (NFFTMAX=1024*1024)

  real d(npts)              ! passband signal
  real h(NFFTMAX/2)         ! real BPF magnitude
  real*8 pc(5),pclast(5)    ! static phase coeffs
  real*8 ac(5),aclast(5)    ! amp coeffs
  real*8 fp

  complex corr(NFFTMAX/2)  ! complex frequency-dependent correction 
  complex c(NFFTMAX)        ! analytic signal

  logical*1 beq            ! boolean static equalizer flag

  data nfft0/0/
  data aclast/0.0,0.0,0.0,0.0,0.0/
  data pclast/0.0,0.0,0.0,0.0,0.0/
!  data ac/1.0,0.05532,0.11438,0.12918,0.09274/ ! amp coeffs for TS2000
  data ac/1.0,0.0,0.0,0.0,0.0/ 

  save corr,nfft0,h,ac,aclast,pclast,pi,t,beta

  df=12000.0/nfft
  nh=nfft/2
  if( nfft.ne.nfft0 ) then
     pi=4.0*atan(1.0)
     t=1.0/2000.0
     beta=0.1
     do i=1,nh+1
        ff=(i-1)*df
        f=ff-1500.0
        h(i)=1.0
        if(abs(f).gt.(1-beta)/(2*t) .and. abs(f).le.(1+beta)/(2*t)) then
           h(i)=h(i)*0.5*(1+cos((pi*t/beta )*(abs(f)-(1-beta)/(2*t))))
        elseif( abs(f) .gt. (1+beta)/(2*t) ) then
           h(i)=0.0
        endif
     enddo
     nfft0=nfft
  endif

  if( any(aclast .ne. ac) .or. any(pclast .ne. pc) ) then
     aclast=ac
     pclast=pc
!     write(*,3001) pc
!3001 format('Phase coeffs:',5f12.6)
     do i=1,nh+1
        ff=(i-1)*df
        f=ff-1500.0
        fp=f/1000.0
        corr(i)=ac(1)+fp*(ac(2)+fp*(ac(3)+fp*(ac(4)+fp*ac(5))))
        pd=fp*fp*(pc(3)+fp*(pc(4)+fp*pc(5))) ! ignore 1st two terms
        corr(i)=corr(i)*cmplx(cos(pd),sin(pd))
     enddo
  endif

  fac=2.0/nfft
  c(1:npts)=fac*d(1:npts)
  c(npts+1:nfft)=0.
  call four2a(c,nfft,1,-1,1)               !Forward c2c FFT

  if( beq ) then
    c(1:nh+1)=h(1:nh+1)*corr(1:nh+1)*c(1:nh+1)
  else
    c(1:nh+1)=h(1:nh+1)*c(1:nh+1)
  endif

  c(1)=0.5*c(1)                            !Half of DC term
  c(nh+2:nfft)=0.                          !Zero the negative frequencies
  call four2a(c,nfft,1,1,1)                !Inverse c2c FFT
  return
end subroutine analytic
Initial Commit 2018-02-08 21:28:33 -05:00			`subroutine analytic(d,npts,nfft,c,pc,beq)`

			`! Convert real data to analytic signal`

			`parameter (NFFTMAX=1024*1024)`

			`real d(npts) ! passband signal`
			`real h(NFFTMAX/2) ! real BPF magnitude`
			`real*8 pc(5),pclast(5) ! static phase coeffs`
			`real*8 ac(5),aclast(5) ! amp coeffs`
			`real*8 fp`

			`complex corr(NFFTMAX/2) ! complex frequency-dependent correction`
			`complex c(NFFTMAX) ! analytic signal`

			`logical*1 beq ! boolean static equalizer flag`

			`data nfft0/0/`
			`data aclast/0.0,0.0,0.0,0.0,0.0/`
			`data pclast/0.0,0.0,0.0,0.0,0.0/`
			`! data ac/1.0,0.05532,0.11438,0.12918,0.09274/ ! amp coeffs for TS2000`
			`data ac/1.0,0.0,0.0,0.0,0.0/`

			`save corr,nfft0,h,ac,aclast,pclast,pi,t,beta`

			`df=12000.0/nfft`
			`nh=nfft/2`
			`if( nfft.ne.nfft0 ) then`
			`pi=4.0*atan(1.0)`
			`t=1.0/2000.0`
			`beta=0.1`
			`do i=1,nh+1`
			`ff=(i-1)*df`
			`f=ff-1500.0`
			`h(i)=1.0`
			`if(abs(f).gt.(1-beta)/(2t) .and. abs(f).le.(1+beta)/(2t)) then`
			`h(i)=h(i)0.5(1+cos((pit/beta )(abs(f)-(1-beta)/(2*t))))`
			`elseif( abs(f) .gt. (1+beta)/(2*t) ) then`
			`h(i)=0.0`
			`endif`
			`enddo`
			`nfft0=nfft`
			`endif`

			`if( any(aclast .ne. ac) .or. any(pclast .ne. pc) ) then`
			`aclast=ac`
			`pclast=pc`
			`! write(*,3001) pc`
			`!3001 format('Phase coeffs:',5f12.6)`
			`do i=1,nh+1`
			`ff=(i-1)*df`
			`f=ff-1500.0`
			`fp=f/1000.0`
			`corr(i)=ac(1)+fp(ac(2)+fp(ac(3)+fp(ac(4)+fpac(5))))`
			`pd=fpfp(pc(3)+fp(pc(4)+fppc(5))) ! ignore 1st two terms`
			`corr(i)=corr(i)*cmplx(cos(pd),sin(pd))`
			`enddo`
			`endif`

			`fac=2.0/nfft`
			`c(1:npts)=fac*d(1:npts)`
			`c(npts+1:nfft)=0.`
			`call four2a(c,nfft,1,-1,1) !Forward c2c FFT`

			`if( beq ) then`
			`c(1:nh+1)=h(1:nh+1)corr(1:nh+1)c(1:nh+1)`
			`else`
			`c(1:nh+1)=h(1:nh+1)*c(1:nh+1)`
			`endif`

			`c(1)=0.5*c(1) !Half of DC term`
			`c(nh+2:nfft)=0. !Zero the negative frequencies`
			`call four2a(c,nfft,1,1,1) !Inverse c2c FFT`
			`return`
			`end subroutine analytic`