dustem_cc.pro
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FUNCTION dustem_cc,wavein,spec,filter_names,cc=cc,fluxconv=fluxconv,no_sort=no_sort,help=help
;+
; NAME:
; dustem_cc
;
; PURPOSE:
; Computes observed SED and color correction for a given spectrum in a given filter
;
; CATEGORY:
; DustEMWrap, Mid-Level, Distributed, Color corrections
;
; CALLING SEQUENCE:
; sed=dustem_cc(wave,spec,filter_names,cc=cc,fluxconv=fluxconv,help=help)
;
; INPUTS:
; wave: array of wavelengths for spec
; spec: spectrum (must be in brightness units)
; filter_names: names of filters for which color correction is
; needed
;
; OPTIONAL INPUT PARAMETERS:
; None
;
; OUTPUTS:
; sed: SED as observed in filters provided in filter_names
;
; OPTIONAL OUTPUT PARAMETERS:
; cc = color correction coefficients (spec*cc=sed)
;
; ACCEPTED KEY-WORDS:
; fluxconv = if set, these are taken for flux conventions
; possible values: 'nuInu=cste', 'FLAMBDA=cste', 'FLAMBDA=cste'
; , 'IRAC', 'MIPS', 'CMB', 'HFI', 'LABOCA', 'NIKA2'
; no_sort = if set, input arrauys are assumed to already be orderd by increasing wavelengths
; help = If set, print this help
;
; COMMON BLOCKS:
; None
;
; SIDE EFFECTS:
; None
;
; RESTRICTIONS:
; The DustEM fortran code must be installed
; The DustEMWrap IDL code must be installed
;
; PROCEDURE:
; None
;
; EXAMPLES
;
; MODIFICATION HISTORY:
; Written JPB Apr-2011
; Evolution details on the DustEMWrap gitlab.
; See http://dustemwrap.irap.omp.eu/ for FAQ and help.
;-
IF keyword_set(help) THEN BEGIN
doc_library,'dustem_cc'
sed=0.
goto,the_end
ENDIF
;eps=1.e-30
eps=0.
;=== constants needed for CMB flux convention
Tcmb=2.725D0
;=== constants needed for MIPS flux convention
h=6.62606876*1d-34 ; J s
c=2.99792458*1d8 ; m*s-1
K=1.380658*1d-23 ; J/K
T_0=1d4 ; calibration star (K units)
fact=h*c
fact3=K*T_0
;sort input, unles /no_sort
IF not keyword_set(no_sort) THEN BEGIN
order =sort(wavein)
spec2 = [eps,spec[order]]
wavein2 = [eps,wavein[order]]
ENDIF ELSE BEGIN
wavein2=wavein
spec2=spec
ENDELSE
IF not keyword_set(fluxconv) THEN BEGIN
fluxconvs=dustem_filter2fluxconv(filter_names)
ENDIF ELSE BEGIN
fluxconvs=fluxconv
ENDELSE
instrus=dustem_filter2instru(filter_names)
inst_tags=tag_names((*!dustem_filters))
Nbands=n_elements(filter_names)
sed=dblarr(Nbands)
cc=dblarr(Nbands)
cc(*)=1.d0
FOR i=0L,Nbands-1 DO BEGIN
iinstru=where(inst_tags EQ instrus(i),countinstr)
IF countinstr EQ 0 THEN BEGIN
message,'Instrument '+instrus(i)+' not found',/continue
stop
ENDIF
st=(*!dustem_filters).(iinstru)
; stop
ii=(where(st.filter_names EQ filter_names[i]))[0]
spec0=interpol(spec2,wavein2,st.central_wavelengths[ii])
IF spec0 EQ 0 THEN BEGIN
sed[i]=spec0
cc[i]=1
goto,next_filter
ENDIF
IF !dustem_do_cc NE 0 and not !dustem_never_do_cc THEN BEGIN ;Color corrections are computed
; print,'DOING color correction calculations'
CASE strupcase(fluxconvs[i]) OF
'HFI0': BEGIN ;This is purely for test (stupid since reads filters each time)
filter_dir=!dustem_wrap_soft_dir+'/Data/FILTERS/'
dir_hfi=filter_dir+'HFI/OFFICIAL'+'/'
; CAUTION: This below should be consistent with what is in dustem_read_filters.pro
; hfi_filter_version='v101'
hfi_filter_version='v201'
bp = hfi_read_bandpass(hfi_filter_version, /rimo,path_rimo=dir_hfi)
spec_int=interpol(spec2,wavein2,*(st.use_wavelengths[ii]))
nu=*(st.use_frequencies(ii))/1.d9
order=sort(nu)
spec_int=spec_int(order)
nu=nu(order)
channel=strtrim(round(dustem_filter2freq(filter_names(i))),2)
;stop
ccc=hfi_color_correction_dustem(bp.name,bp.freq/1.d9,bp.trans,channel, bolo_cc,nu, spec_int)
; ccc=hfi_color_correction(bp,channel, bolo_cc,nu, spec_int)
cc[i]=ccc.cc
END
'HFI': BEGIN
spec_int=interpol(spec2,wavein2,*(st.use_wavelengths(ii)))
nu=*(st.use_frequencies(ii))/1.d9
trans=*(st.use_transmissions(ii))
order=sort(nu)
spec_int=spec_int(order)
nu=nu(order)
trans=trans(order)
channel=strtrim(round(dustem_filter2freq(filter_names(i))),2)
ccc=hfi_color_correction_dustem(channel,nu,trans,channel, bolo_cc,nu, spec_int)
cc[i]=ccc.cc
END
'FNU=CSTE': BEGIN
beta=0.
spec_int=interpol(spec2,wavein2,*(st.use_wavelengths[ii]))
num=integral(*(st.use_wavelengths[ii]),spec_int*(*(st.use_transmissions[ii]))/(*(st.use_wavelengths[ii]))^2.,st.use_wmin[ii],st.use_wmax[ii],/double)
den=integral(*(st.use_wavelengths(ii)),((*(st.use_transmissions(ii)))/((*(st.use_wavelengths(ii)))^(2+beta))),st.use_wmin(ii),st.use_wmax(ii),/double)
; den=integral(*(st.use_wavelengths(ii)),((*(st.use_transmissions(ii)))/(*(st.use_wavelengths(ii)))^2.)),st.use_wmin(ii),st.use_wmax(ii),/double)
; cc[i]=(num*(st.central_wavelengths[ii])^2)/(spec0*den)
cc[i]=num/(spec0*den*(st.central_wavelengths[ii])^beta)
END
'NUINU=CSTE': BEGIN
beta=-1.
spec_int=interpol(spec2,wavein2,*(st.use_wavelengths(ii)))
num=integral(*(st.use_wavelengths(ii)),spec_int*(*(st.use_transmissions(ii)))/(*(st.use_wavelengths(ii)))^2.,st.use_wmin(ii),st.use_wmax(ii),/double)
den=integral(*(st.use_wavelengths(ii)),((*(st.use_transmissions(ii)))/((*(st.use_wavelengths(ii)))^(2+beta))),st.use_wmin(ii),st.use_wmax(ii),/double)
; den=integral(*(st.use_wavelengths(ii)),((*(st.use_transmissions(ii)))/(*(st.use_wavelengths(ii)))^1.)),st.use_wmin(ii),st.use_wmax(ii),/double)
; cc[i]=num/den/spec0*(st.central_wavelengths(ii))
cc[i]=num/(spec0*den*(st.central_wavelengths[ii])^beta)
END
'FLAMBDA=CSTE': BEGIN
beta=-2.
spec_int=interpol(spec2,wavein2,*(st.use_wavelengths[ii]))
num=integral(*(st.use_wavelengths[ii]),spec_int*(*(st.use_transmissions[ii]))/(*(st.use_wavelengths[ii]))^2.,st.use_wmin[ii],st.use_wmax[ii],/double)
den=integral(*(st.use_wavelengths(ii)),((*(st.use_transmissions(ii)))/((*(st.use_wavelengths(ii)))^(2+beta))),st.use_wmin(ii),st.use_wmax(ii),/double)
; den=integral(*(st.use_wavelengths[ii]),(*(st.use_transmissions[ii])),st.use_wmin[ii],st.use_wmax[ii],/double)
; cc[i]=(num*(st.central_wavelengths[ii])^2)/(spec0*den)
cc[i]=num/(spec0*den*(st.central_wavelengths[ii])^beta)
END
'MIPS': BEGIN
expon=exp(fact/(*(st.use_wavelengths(ii))*1e-6*fact3))-1.
spec_int=interpol(spec2,wavein2,*(st.use_wavelengths(ii)))
num=integral(*(st.use_wavelengths(ii)),spec_int*(*(st.use_transmissions(ii)))/(*(st.use_wavelengths(ii)))^2.,st.use_wmin(ii),st.use_wmax(ii),/double)
den=integral(*(st.use_wavelengths(ii)),*(st.use_transmissions(ii))/(*(st.use_wavelengths(ii)))^5/expon,st.use_wmin(ii),st.use_wmax(ii),/double)
ffact=st.central_wavelengths(ii)*1e-6*K*T_0
cc[i]=num/den/spec0/(st.central_wavelengths(ii))^3/(exp(fact/ffact)-1.)
END
'IRAC': BEGIN
spec_int=interpol(spec2,wavein2,*(st.use_wavelengths(ii)))
num=integral(*(st.use_wavelengths(ii)),spec_int*(*(st.use_transmissions(ii)))/(*(st.use_wavelengths(ii))),st.use_wmin(ii),st.use_wmax(ii),/double)
den=integral(*(st.use_wavelengths(ii)),*(st.use_transmissions(ii)),st.use_wmin(ii),st.use_wmax(ii),/double)
cc[i]=num/den/spec0*(st.central_wavelengths(ii))
END
'CMB': BEGIN
spec_int=interpol(spec2,wavein2,*(st.use_wavelengths(ii)))
num=integral(*(st.use_wavelengths(ii)),spec_int*(*(st.use_transmissions(ii)))/(*(st.use_wavelengths(ii)))^2.,st.use_wmin(ii),st.use_wmax(ii),/double)
den=integral(*(st.use_wavelengths(ii)),(*(st.use_transmissions(ii)))/(*(st.use_wavelengths(ii))^2)*dustem_planck_function(Tcmb,*(st.use_wavelengths(ii))),st.use_wmin(ii),st.use_wmax(ii),/double)
cc[i]=num/den*dustem_planck_function(Tcmb,st.central_wavelengths(ii))/spec0
END
'LABOCA': BEGIN
; spec_int=interpol(spec2,wavein2,*(st.use_wavelengths(ii)))
; num=integral(*(st.use_wavelengths(ii)),spec_int*(*(st.use_transmissions(ii))),st.use_wmin(ii),st.use_wmax(ii),/double)
; den=integral(*(st.use_wavelengths(ii)),*(st.use_transmissions(ii))/(*(st.use_wavelengths(ii))^2.5),st.use_wmin(ii),st.use_wmax(ii),/double)
; cc(i)=num/den/spec0/(st.central_wavelengths(ii))^2.5
alpha_new=0.
spec_int=interpol(spec2,wavein2,*(st.use_wavelengths(ii)))
num=integral(*(st.use_wavelengths(ii)),spec_int*(*(st.use_transmissions(ii)))/(*(st.use_wavelengths(ii))),st.use_wmin(ii),st.use_wmax(ii),/double)
den=integral(*(st.use_wavelengths(ii)),*(st.use_transmissions(ii))/(*(st.use_wavelengths(ii))^(alpha_new+2.)),st.use_wmin(ii),st.use_wmax(ii),/double)
cc[i]=num/den/spec0*(st.central_wavelengths(ii))^(-(alpha_new+1.))
END
'NIKA2': BEGIN
beta=1.6
spec_int=interpol(spec2,wavein2,*(st.use_wavelengths(ii)))
num=integral(*(st.use_wavelengths(ii)),spec_int*(*(st.use_transmissions(ii)))/(*(st.use_wavelengths(ii)))^2.,st.use_wmin(ii),st.use_wmax(ii),/double)
den=integral(*(st.use_wavelengths(ii)),((*(st.use_transmissions(ii)))/((*(st.use_wavelengths(ii)))^(2+beta))),st.use_wmin(ii),st.use_wmax(ii),/double)
cc[i]=num/(spec0*den*(st.central_wavelengths[ii])^beta)
END
ELSE:BEGIN
message,strupcase(fluxconvs[i])+' not recognized, assuming NUINU=CSTE',/info
;cc[i]=1. ; changed default behaviour in version 4.3
beta=-1.
spec_int=interpol(spec2,wavein2,*(st.use_wavelengths(ii)))
num=integral(*(st.use_wavelengths(ii)),spec_int*(*(st.use_transmissions(ii)))/(*(st.use_wavelengths(ii)))^2.,st.use_wmin(ii),st.use_wmax(ii),/double)
den=integral(*(st.use_wavelengths(ii)),((*(st.use_transmissions(ii)))/((*(st.use_wavelengths(ii)))^(2+beta))),st.use_wmin(ii),st.use_wmax(ii),/double)
cc[i]=num/(spec0*den*(st.central_wavelengths[ii])^beta)
END
ENDCASE
!dustem_previous_cc=ptr_new(cc)
ENDIF ELSE BEGIN ;When no new cc calculation is required
IF !dustem_never_do_cc EQ 0 THEN BEGIN
cc=(*!dustem_previous_cc)
ENDIF
ENDELSE
IF finite(cc[i]) THEN sed[i]=spec0*cc[i] ELSE sed[i]=spec0
next_filter:
ENDFOR
the_end:
RETURN,sed
END