FUNCTION dustem_plugin_freefree,key=key,val=val,scope=scope,paramtag=paramtag,paramdefault=paramdefault,help=help ;+ ; NAME: ; dustem_plugin_freefree ; PURPOSE: ; DUSTEM plugin to compute free-free emission ; CATEGORY: ; DUSTEM Wrapper ; CALLING SEQUENCE: ; freefree=dustem_plugin_freefree([,key=][,val=]) ; INPUTS: ; None ; OPTIONAL INPUT PARAMETERS: ; key = input parameter number ; val = input parameter value ; OUTPUTS: ; freefree = free-free spectrum (on dustem wavelengths) ; OPTIONAL OUTPUT PARAMETERS: ; scope = scope of the plugin ; paramdefault = default values of parameters ; paramtag = plugin parameter names as strings ; ACCEPTED KEY-WORDS: ; help = if set, print this help ; COMMON BLOCKS: ; None ; SIDE EFFECTS: ; None ; RESTRICTIONS: ; None ; PROCEDURE: ; This is a dustem plugin ; EXAMPLES ; dustem_init ; vec=dustem_plugin_freefree(scope=scope) ; MODIFICATION HISTORY: ; Written by JPB ;- IF keyword_set(help) THEN BEGIN doc_library,'dustem_plugin_freefree' output=0. goto,the_end ENDIF ;default values of input parameters Tgas=10000. ;default gas temperature Amplitude=1. ;Amplitude smallp=0.0 ;default polarization fraction psi=0. ;default polarization angle scope='ADD_SED' paramtag=['T_gas (K)','Amp','p','Psi (deg)'] paramdefault=[Tgas,Amplitude,smallp,psi] IF keyword_set(key) THEN BEGIN a=where(key EQ 1,count1) b=where(key EQ 2,count2) c=where(key EQ 3,count3) ;default polarization fraction -newly added d=where(key EQ 4,count4) ;default polarization angle -newly added IF count1 NE 0 then Tgas=(val(a))(0) IF count2 NE 0 then Amplitude=(val(b))(0) IF count3 NE 0 then smallp=val[c[0]] ;-newly added IF count4 NE 0 then psi=val[d[0]] ;-newly added ENDIF ;IF !dustem_which EQ 'DESERT' THEN BEGIN ; lambir=((*!dustem_params).gemissiv.lambir) ;ENDIF ELSE BEGIN ; lambir=((*!dustem_params).lambda.lambda) ;ENDELSE ;replaced by the following to ease the life of plugins writters lambir=dustem_get_wavelengths() Nwavs=n_elements(lambir) cmic=3.e14 nu=cmic/lambir ;Hz mjy=1 ;output is in MJy/sr lambir_ref=10000. output=fltarr(Nwavs,5) ;newly added ;stop ;use_method='Deschenes2008' ;use_method='WallsGabaud1998' use_method='Dickinson2003_norm' CASE use_method OF 'WallsGabaud1998':BEGIN em=1. ;This is a stupid value for the Emission measure. Result will be rescaled based on I_halpha_R anyway output[*,0]=intensity_free_free(nu,Tgas,em,I_halpha_R=I_halpha_R,nHe=nHe,ergs=ergs,mjy=mjy) fact=Amplitude/I_halpha_R ;=== normalize to the requested Halpha value. output[*,0]=output[*,0]*fact END 'WallsGabaud1998_scaled':BEGIN em=1. ;This is a stupid value for the Emission measure. Result will be rescaled based on I_halpha_R anyway output[*,0]=intensity_free_free(nu,Tgas,em,I_halpha_R=I_halpha_R,nHe=nHe,ergs=ergs,mjy=mjy) norm=interpol(output[*,0],lambir,lambir_ref) output[*,0]=output[*,0]/norm*Amplitude END 'Deschenes2008':BEGIN beta_freefree=2.+1./(10.48+1.5*alog(Tgas/8.e3)-alog(nu/1.e9)) output[*,0]=nu^(-1.*beta_freefree) norm=interpol(output[*,0],lambir,lambir_ref) output[*,0]=output[*,0]/norm*Amplitude END 'Dickinson2003_norm':BEGIN ;stop em=1. T4=Tgas/1.e4 nu_ghz=nu/1.e9 a=0.366*(nu_ghz/1.e9)^(-0.15)*(alog(4.995*1e-2*(nu_ghz)^(-1.))+1.5*alog(Tgas)) Tb=8.369e3*a*(nu_ghz)^(-2.)*T4^0.667*10^(0.029*T4)*(1.+0.08) ;in mK for 1 Rayleigh convert_mk_mjy, lambir, Tb, I_Mjy, /RJ norm=interpol(I_Mjy,lambir,lambir_ref) output[*,0]=I_Mjy/norm*Amplitude END ENDCASE ;polarization this actually need to polar_ippsi2iqu,output[*,0],Q,U,replicate(smallp,Nwavs),replicate(psi,Nwavs) output[*,1]=Q output[*,2]=U output[*,3]=replicate(smallp,Nwavs) output[*,4]=replicate(psi,Nwavs) the_end: RETURN,output END