source: LMDZ6/branches/LMDZ_ECRad/libf/phylmd/cosp2/icarus.F90 @ 5306

Last change on this file since 5306 was 3358, checked in by idelkadi, 6 years ago

Implementation de la nouvelle version COSPv2 dans LMDZ.
Pour compiler avec makelmdz_fcma utiliser l'option "-cosp2 true"

File size: 30.1 KB
Line 
1! %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
2! Copyright (c) 2009, Lawrence Livemore National Security Limited Liability
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24! OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
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27! OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
28!
29! History
30! May 2015 - D. Swales - Modified for COSPv2.0
31! %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
32MODULE MOD_ICARUS
33  USE COSP_KINDS,          ONLY: wp
34  USE COSP_PHYS_CONSTANTS, ONLY: amd,amw,avo,grav
35  use MOD_COSP_STATS,      ONLY: hist2D
36  USE MOD_COSP_CONFIG,     ONLY: R_UNDEF,numISCCPTauBins,numISCCPPresBins,isccp_histTau, &
37                                 isccp_histPres
38  implicit none
39 
40  ! Shared Parameters                   
41  integer,parameter :: &
42       ncolprint = 0 ! Flag for debug printing (set as parameter to increase performance)
43
44  ! Cloud-top height determination
45  integer :: &
46       isccp_top_height,          & ! Top height adjustment method
47       isccp_top_height_direction   ! Direction for finding atmosphere pressure level
48
49  ! Parameters used by icarus
50  real(wp),parameter :: &
51       tauchk = -1._wp*log(0.9999999_wp), & ! Lower limit on optical depth
52       isccp_taumin = 0.3_wp,             & ! Minimum optical depth for joint-hostogram
53       pstd = 1013250._wp,                & ! Mean sea-level pressure (Pa)
54       isccp_t0 = 296._wp,                & ! Mean surface temperature (K)
55       output_missing_value = -1.E+30       ! Missing values
56
57contains
58  ! ##########################################################################
59  ! ##########################################################################
60  SUBROUTINE ICARUS(debug,debugcol,npoints,sunlit,nlev,ncol,pfull,          &
61                    phalf,qv,cc,conv,dtau_s,dtau_c,th,thd,frac_out,skt,emsfc_lw,at,&
62                    dem_s,dem_c,fq_isccp,totalcldarea, meanptop,meantaucld, &
63                    meanalbedocld, meantb,meantbclr,boxtau,boxptop,levmatch)
64       
65    ! INPUTS
66    INTEGER,intent(in) ::      & !
67         npoints,              & ! Number of model points in the horizontal
68         nlev,                 & ! Number of model levels in column
69         ncol,                 & ! Number of subcolumns
70         debug,                & ! Debug flag
71         debugcol                ! Debug column flag
72    INTEGER,intent(in),dimension(npoints) :: & !
73         sunlit                  ! 1 for day points, 0 for night time
74    REAL(WP),intent(in) ::     & !
75         emsfc_lw                ! 10.5 micron emissivity of surface (fraction) 
76    REAL(WP),intent(in),dimension(npoints) :: & !
77         skt                     ! Skin Temperature (K)
78    REAL(WP),intent(in),dimension(npoints,ncol,nlev) :: & !
79         frac_out                ! Boxes gridbox divided up into subcolumns
80    REAL(WP),intent(in),dimension(npoints,nlev) :: & !
81         pfull,                & ! Pressure of full model levels (Pascals)
82         qv,                   & ! Water vapor specific humidity (kg vapor/ kg air)
83         cc,                   & ! Cloud cover in each model level (fraction)
84         conv,                 & ! Convective cloud cover in each model
85         at,                   & ! Temperature in each model level (K)
86         dem_c,                & ! Emissivity for convective clouds
87         dem_s,                & ! Emissivity for stratiform clouds
88         dtau_c,               & ! Optical depth for convective clouds
89         dtau_s                  ! Optical depth for stratiform clouds
90    REAL(WP),intent(in),dimension(npoints,nlev+1) :: & !
91         phalf                   ! Pressure of half model levels (Pascals)!
92    integer,intent(in) :: th,thd
93
94    ! OUTPUTS
95    REAL(WP),intent(out),dimension(npoints,7,7) :: &
96         fq_isccp                ! The fraction of the model grid box covered by clouds
97    REAL(WP),intent(out),dimension(npoints) :: &
98         totalcldarea,         & ! The fraction of model grid box columns with cloud present
99         meanptop,             & ! Mean cloud top pressure (mb) - linear averaging
100         meantaucld,           & ! Mean optical thickness
101         meanalbedocld,        & ! Mean cloud albedo 
102         meantb,               & ! Mean all-sky 10.5 micron brightness temperature
103         meantbclr               ! Mean clear-sky 10.5 micron brightness temperature
104    REAL(WP),intent(out),dimension(npoints,ncol) :: &
105         boxtau,               & ! Optical thickness in each column
106         boxptop                 ! Cloud top pressure (mb) in each column
107    INTEGER,intent(out),dimension(npoints,ncol) :: &
108         levmatch                ! Used for icarus unit testing only
109
110
111    ! INTERNAL VARIABLES
112    CHARACTER(len=10)                     :: ftn09
113    REAL(WP),dimension(npoints,ncol)      :: boxttop
114    REAL(WP),dimension(npoints,ncol,nlev) :: dtau,demIN
115    INTEGER                               :: j,ilev,ibox
116    INTEGER,dimension(nlev,ncol   )       :: acc
117
118    ! PARAMETERS
119    character ,parameter, dimension(6) :: cchar=(/' ','-','1','+','I','+'/)
120    character(len=1),parameter,dimension(6) :: cchar_realtops=(/ ' ',' ','1','1','I','I'/)
121    ! ##########################################################################
122   
123    call cosp_simulator_optics(npoints,ncol,nlev,frac_out,dem_c,dem_s,demIN)
124    call cosp_simulator_optics(npoints,ncol,nlev,frac_out,dtau_c,dtau_s,dtau)
125
126    call ICARUS_SUBCOLUMN(npoints,ncol,nlev,sunlit,dtau,demIN,skt,emsfc_lw,qv,at,        &
127                      pfull,phalf,frac_out,levmatch,boxtau,boxptop,boxttop,meantbclr)
128
129    call ICARUS_COLUMN(npoints,ncol,boxtau,boxptop/100._wp,sunlit,boxttop,&
130                       fq_isccp,meanalbedocld,meanptop,meantaucld,totalcldarea,meantb)
131
132    ! ##########################################################################
133    ! OPTIONAL PRINTOUT OF DATA TO CHECK PROGRAM
134    ! ##########################################################################
135   
136    if (debugcol.ne.0) then
137       do j=1,npoints,debugcol
138         
139          ! Produce character output
140          do ilev=1,nlev
141             acc(ilev,1:ncol)=frac_out(j,1:ncol,ilev)*2
142             where(levmatch(j,1:ncol) .eq. ilev) acc(ilev,1:ncol)=acc(ilev,1:ncol)+1
143          enddo
144         
145          write(ftn09,11) j
14611        format('ftn09.',i4.4)
147          open(9, FILE=ftn09, FORM='FORMATTED')
148         
149          write(9,'(a1)') ' '
150          write(9,'(10i5)') (ilev,ilev=5,nlev,5)
151          write(9,'(a1)') ' '
152         
153          do ibox=1,ncol
154             write(9,'(40(a1),1x,40(a1))') &
155                  (cchar_realtops(acc(ilev,ibox)+1),ilev=1,nlev),&
156                  (cchar(acc(ilev,ibox)+1),ilev=1,nlev)
157          end do
158          close(9)
159
160       enddo       
161    end if
162   
163    return
164  end SUBROUTINE ICARUS
165 
166  ! ############################################################################
167  ! ############################################################################
168  ! ############################################################################
169  SUBROUTINE ICARUS_SUBCOLUMN(npoints,ncol,nlev,sunlit,dtau,demiN,skt,emsfc_lw,qv,at,        &
170                          pfull,phalf,frac_out,levmatch,boxtau,boxptop,boxttop,meantbclr)
171    ! Inputs
172    INTEGER, intent(in) ::   &
173         ncol,               & ! Number of subcolumns
174         npoints,            & ! Number of horizontal gridpoints
175         nlev                  ! Number of vertical levels
176    INTEGER, intent(in), dimension(npoints) :: &
177         sunlit                ! 1=day 0=night
178    REAL(WP),intent(in) :: &
179         emsfc_lw              ! 10.5 micron emissivity of surface (fraction)
180    REAL(WP),intent(in), dimension(npoints) ::  &
181         skt                   ! Skin temperature
182    REAL(WP),intent(in), dimension(npoints,nlev) ::  &
183         at,                 & ! Temperature
184         pfull,              & ! Presure
185         qv                    ! Specific humidity
186    REAL(WP),intent(in), dimension(npoints,ncol,nlev) :: &
187         frac_out,           & ! Subcolumn cloud cover
188         dtau,               & ! Subcolumn optical thickness
189         demIN                 ! Subcolumn emissivity
190    REAL(WP),intent(in), dimension(npoints,nlev+1) :: &
191         phalf                 ! Pressure at model half levels
192
193    ! Outputs
194    REAL(WP),intent(inout),dimension(npoints) :: &
195         meantbclr             ! Mean clear-sky 10.5 micron brightness temperature
196    REAL(WP),intent(inout),dimension(npoints,ncol) :: &
197         boxtau,             & ! Optical thickness in each column
198         boxptop,            & ! Cloud top pressure (mb) in each column
199         boxttop               ! Cloud top temperature in each column
200    INTEGER, intent(inout),dimension(npoints,ncol)      :: levmatch
201
202    ! Local Variables
203    INTEGER :: &
204       j,ibox,ilev,k1,k2,icycle
205    INTEGER,dimension(npoints) :: &
206       nmatch,itrop
207    INTEGER,dimension(npoints,nlev-1) :: &
208       match
209    REAL(WP) :: &
210       logp,logp1,logp2,atd
211    REAL(WP),dimension(npoints) :: &
212       bb,attropmin,attrop,ptrop,atmax,btcmin,transmax,tauir,taumin,fluxtopinit,press,   &
213       dpress,atmden,rvh20,rhoave,rh20s,rfrgn,tmpexp,tauwv,wk,trans_layers_above_clrsky, &
214       fluxtop_clrsky
215    REAL(WP),dimension(npoints,nlev) :: &
216       dem_wv
217    REAL(WP),dimension(npoints,ncol) :: &
218       trans_layers_above,dem,tb,emcld,fluxtop,tau,ptop
219
220    ! ####################################################################################
221    ! Compute cloud optical depth for each column by summing up subcolumns
222    tau(1:npoints,1:ncol) = 0._wp
223    tau(1:npoints,1:ncol) = sum(dtau,dim=3)
224
225    ! Set tropopause values
226    if (isccp_top_height .eq. 1 .or. isccp_top_height .eq. 3) then
227       ptrop(1:npoints)     = 5000._wp
228       attropmin(1:npoints) = 400._wp
229       atmax(1:npoints)     = 0._wp
230       attrop(1:npoints)    = 120._wp
231       itrop(1:npoints)     = 1
232
233       do ilev=1,nlev
234          where(pfull(1:npoints,ilev) .lt. 40000. .and. &
235                pfull(1:npoints,ilev) .gt.  5000. .and. &
236                at(1:npoints,ilev)    .lt. attropmin(1:npoints))
237             ptrop(1:npoints)     = pfull(1:npoints,ilev)
238             attropmin(1:npoints) = at(1:npoints,ilev)
239             attrop(1:npoints)    = attropmin(1:npoints)
240             itrop     = ilev
241          endwhere
242       enddo
243
244       do ilev=1,nlev
245          atmax(1:npoints) = merge(at(1:npoints,ilev),atmax(1:npoints),&
246               at(1:npoints,ilev) .gt. atmax(1:npoints) .and. ilev  .ge. itrop(1:npoints))
247       enddo
248    end if
249 
250    if (isccp_top_height .eq. 1 .or. isccp_top_height .eq. 3) then
251       ! ############################################################################
252       !                        Clear-sky radiance calculation
253       !       
254       ! Compute water vapor continuum emissivity this treatment follows Schwarkzopf
255       ! and Ramasamy JGR 1999,vol 104, pages 9467-9499. The emissivity is calculated
256       ! at a wavenumber of 955 cm-1, or 10.47 microns
257       ! ############################################################################
258       do ilev=1,nlev
259          press(1:npoints)  = pfull(1:npoints,ilev)*10._wp
260          dpress(1:npoints) = (phalf(1:npoints,ilev+1)-phalf(1:npoints,ilev))*10
261          atmden(1:npoints) = dpress(1:npoints)/(grav*100._wp)
262          rvh20(1:npoints)  = qv(1:npoints,ilev)*amd/amw
263          wk(1:npoints)     = rvh20(1:npoints)*avo*atmden/amd
264          rhoave(1:npoints) = (press(1:npoints)/pstd)*(isccp_t0/at(1:npoints,ilev))
265          rh20s(1:npoints)  = rvh20(1:npoints)*rhoave(1:npoints)
266          rfrgn(1:npoints)  = rhoave(1:npoints)-rh20s(1:npoints)
267          tmpexp(1:npoints) = exp(-0.02_wp*(at(1:npoints,ilev)-isccp_t0))
268          tauwv(1:npoints)  = wk(1:npoints)*1.e-20*((0.0224697_wp*rh20s(1:npoints)*      &
269                              tmpexp(1:npoints))+(3.41817e-7*rfrgn(1:npoints)))*0.98_wp
270          dem_wv(1:npoints,ilev) = 1._wp - exp( -1._wp * tauwv(1:npoints))
271       enddo
272
273       fluxtop_clrsky(1:npoints)            = 0._wp
274       trans_layers_above_clrsky(1:npoints) = 1._wp
275       do ilev=1,nlev
276          ! Black body emission at temperature of the layer
277          bb(1:npoints) = 1._wp / ( exp(1307.27_wp/at(1:npoints,ilev)) - 1._wp )
278         
279          ! Increase TOA flux by flux emitted from layer times total transmittance in layers above
280          fluxtop_clrsky(1:npoints) = fluxtop_clrsky(1:npoints) + &
281               dem_wv(1:npoints,ilev)*bb(1:npoints)*trans_layers_above_clrsky(1:npoints)
282         
283          ! Update trans_layers_above with transmissivity from this layer for next time around loop
284          trans_layers_above_clrsky(1:npoints) = trans_layers_above_clrsky(1:npoints)*&
285              (1.-dem_wv(1:npoints,ilev))               
286       enddo
287
288       ! Add in surface emission
289       bb(1:npoints) = 1._wp/( exp(1307.27_wp/skt(1:npoints)) - 1._wp )
290       fluxtop_clrsky(1:npoints) = fluxtop_clrsky(1:npoints) + &
291           emsfc_lw * bb(1:npoints)*trans_layers_above_clrsky(1:npoints)
292
293       ! Clear Sky brightness temperature
294       meantbclr(1:npoints) = 1307.27_wp/(log(1._wp+(1._wp/fluxtop_clrsky(1:npoints))))
295       
296       ! #################################################################################
297       !                        All-sky radiance calculation
298       ! #################################################################################
299       
300       fluxtop(1:npoints,1:ncol)            = 0._wp
301       trans_layers_above(1:npoints,1:ncol) = 1._wp
302       do ilev=1,nlev
303          ! Black body emission at temperature of the layer
304          bb=1._wp/(exp(1307.27_wp/at(1:npoints,ilev)) - 1._wp)
305         
306          do ibox=1,ncol
307             ! Emissivity
308             dem(1:npoints,ibox) = merge(dem_wv(1:npoints,ilev), &
309                                         1._wp-(1._wp-demIN(1:npoints,ibox,ilev))*(1._wp-dem_wv(1:npoints,ilev)), &
310                                         demIN(1:npoints,ibox,ilev) .eq. 0)
311
312             ! Increase TOA flux emitted from layer
313             fluxtop(1:npoints,ibox) = fluxtop(1:npoints,ibox) + dem(1:npoints,ibox)*bb*trans_layers_above(1:npoints,ibox)
314             
315             ! Update trans_layer by emitted layer from above
316             trans_layers_above(1:npoints,ibox) = trans_layers_above(1:npoints,ibox)*(1._wp-dem(1:npoints,ibox))
317          enddo
318       enddo
319
320       ! Add in surface emission
321       bb(1:npoints)=1._wp/( exp(1307.27_wp/skt(1:npoints)) - 1._wp )
322       do ibox=1,ncol
323          fluxtop(1:npoints,ibox) = fluxtop(1:npoints,ibox) + emsfc_lw*bb(1:npoints)*trans_layers_above(1:npoints,ibox)
324       end do
325
326       ! All Sky brightness temperature
327       boxttop(1:npoints,1:ncol) = 1307.27_wp/(log(1._wp+(1._wp/fluxtop(1:npoints,1:ncol))))
328
329       ! ################################################################################# 
330       !                            Cloud-Top Temperature
331       !
332       ! Now that you have the top of atmosphere radiance, account for ISCCP
333       ! procedures to determine cloud top temperature account for partially
334       ! transmitting cloud recompute flux ISCCP would see assuming a single layer
335       ! cloud. *NOTE* choice here of 2.13, as it is primarily ice clouds which have
336       ! partial emissivity and need the adjustment performed in this section. If it
337       ! turns out that the cloud brightness temperature is greater than 260K, then
338       ! the liquid cloud conversion factor of 2.56 is used. *NOTE* that this is
339       ! discussed on pages 85-87 of the ISCCP D level documentation
340       ! (Rossow et al. 1996)
341       ! #################################################################################
342
343       ! Compute minimum brightness temperature and optical depth
344       btcmin(1:npoints) = 1._wp /  ( exp(1307.27_wp/(attrop(1:npoints)-5._wp)) - 1._wp )
345
346       do ibox=1,ncol
347          transmax(1:npoints) = (fluxtop(1:npoints,ibox)-btcmin) /(fluxtop_clrsky(1:npoints)-btcmin(1:npoints))
348          tauir(1:npoints)    = tau(1:npoints,ibox)/2.13_wp
349          taumin(1:npoints)   = -log(max(min(transmax(1:npoints),0.9999999_wp),0.001_wp))
350          if (isccp_top_height .eq. 1) then
351             do j=1,npoints 
352                if (transmax(j) .gt. 0.001 .and.  transmax(j) .le. 0.9999999) then
353                   fluxtopinit(j) = fluxtop(j,ibox)
354                   tauir(j) = tau(j,ibox)/2.13_wp
355                endif
356             enddo
357             do icycle=1,2
358                do j=1,npoints 
359                   if (tau(j,ibox) .gt. (tauchk)) then
360                      if (transmax(j) .gt. 0.001 .and.  transmax(j) .le. 0.9999999) then
361                         emcld(j,ibox) = 1._wp - exp(-1._wp * tauir(j)  )
362                         fluxtop(j,ibox) = fluxtopinit(j) - ((1.-emcld(j,ibox))*fluxtop_clrsky(j))
363                         fluxtop(j,ibox)=max(1.E-06_wp,(fluxtop(j,ibox)/emcld(j,ibox)))
364                         tb(j,ibox)= 1307.27_wp / (log(1._wp + (1._wp/fluxtop(j,ibox))))
365                         if (tb(j,ibox) .gt. 260.) then
366                            tauir(j) = tau(j,ibox) / 2.56_wp
367                         end if
368                      end if
369                   end if
370                enddo
371            enddo
372          endif
373
374          ! Cloud-top temperature
375          where(tau(1:npoints,ibox) .gt. tauchk)
376             tb(1:npoints,ibox)= 1307.27_wp/ (log(1. + (1._wp/fluxtop(1:npoints,ibox))))
377             where (isccp_top_height .eq. 1 .and. tauir(1:npoints) .lt. taumin(1:npoints))
378                tb(1:npoints,ibox) = attrop(1:npoints) - 5._wp
379                tau(1:npoints,ibox) = 2.13_wp*taumin(1:npoints)
380             endwhere
381          endwhere
382         
383          ! Clear-sky brightness temperature
384          where(tau(1:npoints,ibox) .le. tauchk)
385             tb(1:npoints,ibox) = meantbclr(1:npoints)
386          endwhere
387       enddo
388    else
389       meantbclr(1:npoints) = output_missing_value
390    end if
391
392    ! ####################################################################################
393    !                           Cloud-Top Pressure
394    !
395    ! The 2 methods differ according to whether or not you use the physical cloud
396    ! top pressure (isccp_top_height = 2) or the radiatively determined cloud top
397    ! pressure (isccp_top_height = 1 or 3)
398    ! ####################################################################################
399    do ibox=1,ncol
400       !segregate according to optical thickness
401       if (isccp_top_height .eq. 1 .or. isccp_top_height .eq. 3) then 
402         
403          ! Find level whose temperature most closely matches brightness temperature
404          nmatch(1:npoints)=0
405          do k1=1,nlev-1
406             ilev = merge(nlev-k1,k1,isccp_top_height_direction .eq. 2)       
407             do j=1,npoints
408                if (ilev           .ge. itrop(j)     .and. &
409                     ((at(j,ilev)  .ge. tb(j,ibox)   .and. & 
410                      at(j,ilev+1) .le. tb(j,ibox))  .or.  &
411                      (at(j,ilev)  .le. tb(j,ibox)   .and. &
412                      at(j,ilev+1) .ge. tb(j,ibox)))) then
413                   nmatch(j)=nmatch(j)+1
414                   match(j,nmatch(j))=ilev
415                endif
416             enddo
417          enddo
418
419          do j=1,npoints
420             if (nmatch(j) .ge. 1) then
421                k1 = match(j,nmatch(j))
422                k2 = k1 + 1
423                logp1 = log(pfull(j,k1))
424                logp2 = log(pfull(j,k2))
425                atd = max(tauchk,abs(at(j,k2) - at(j,k1)))
426                logp=logp1+(logp2-logp1)*abs(tb(j,ibox)-at(j,k1))/atd
427                ptop(j,ibox) = exp(logp)
428                levmatch(j,ibox) = merge(k1,k2,abs(pfull(j,k1)-ptop(j,ibox)) .lt. abs(pfull(j,k2)-ptop(j,ibox)))
429             else
430                if (tb(j,ibox) .le. attrop(j)) then
431                   ptop(j,ibox)=ptrop(j)
432                   levmatch(j,ibox)=itrop(j)
433                end if
434                if (tb(j,ibox) .ge. atmax(j)) then
435                   ptop(j,ibox)=pfull(j,nlev)
436                   levmatch(j,ibox)=nlev
437                end if
438             end if
439          enddo
440       else
441          ptop(1:npoints,ibox)=0.
442          do ilev=1,nlev
443             where((ptop(1:npoints,ibox) .eq. 0. ) .and.(frac_out(1:npoints,ibox,ilev) .ne. 0))
444                ptop(1:npoints,ibox)=phalf(1:npoints,ilev)
445                levmatch(1:npoints,ibox)=ilev
446             endwhere
447          end do
448       end if
449       where(tau(1:npoints,ibox) .le. tauchk)
450          ptop(1:npoints,ibox)=0._wp
451          levmatch(1:npoints,ibox)=0._wp
452       endwhere
453    enddo
454
455    ! ####################################################################################
456    !                Compute subcolumn pressure and optical depth
457    ! ####################################################################################
458    boxtau(1:npoints,1:ncol)  = output_missing_value
459    boxptop(1:npoints,1:ncol) = output_missing_value
460    do ibox=1,ncol
461       do j=1,npoints
462          if (tau(j,ibox) .gt. (tauchk) .and. ptop(j,ibox) .gt. 0.) then
463             if (sunlit(j).eq.1 .or. isccp_top_height .eq. 3) then
464                boxtau(j,ibox) = tau(j,ibox)
465                boxptop(j,ibox) = ptop(j,ibox)!/100._wp
466             endif
467          endif
468       enddo
469    enddo
470
471  end SUBROUTINE ICARUS_SUBCOLUMN
472
473  ! ######################################################################################
474  ! SUBROUTINE icarus_column
475  ! ######################################################################################
476  SUBROUTINE ICARUS_column(npoints,ncol,boxtau,boxptop,sunlit,boxttop,fq_isccp,     &
477                           meanalbedocld,meanptop,meantaucld,totalcldarea,meantb)
478    ! Inputs
479    INTEGER, intent(in) :: &
480         ncol,    & ! Number of subcolumns
481         npoints    ! Number of horizontal gridpoints
482    INTEGER, intent(in),dimension(npoints) :: &
483         sunlit     ! day=1 night=0
484    REAL(WP),intent(in),dimension(npoints,ncol) ::  &
485         boxttop,  & ! Subcolumn top temperature
486         boxptop,  & ! Subcolumn cloud top pressure
487         boxtau      ! Subcolumn optical depth
488
489    ! Outputs
490    REAL(WP),intent(inout),dimension(npoints) :: &
491         meanalbedocld, & ! Gridmean cloud albedo
492         meanptop,      & ! Gridmean cloud top pressure (mb) - linear averaging
493         meantaucld,    & ! Gridmean optical thickness
494         totalcldarea,  & ! The fraction of model grid box columns with cloud present
495         meantb           ! Gridmean all-sky 10.5 micron brightness temperature
496    REAL(WP),intent(inout),dimension(npoints,7,7) :: &
497         fq_isccp         ! The fraction of the model grid box covered by clouds
498
499    ! Local Variables
500    INTEGER :: j,ilev,ilev2
501    REAL(WP),dimension(npoints,ncol) :: albedocld
502    LOGICAL, dimension(npoints,ncol) :: box_cloudy
503
504    ! Variables for new joint-histogram implementation
505    logical,dimension(ncol) :: box_cloudy2
506
507    ! ####################################################################################
508    !                           Brightness Temperature
509    ! ####################################################################################
510    if (isccp_top_height .eq. 1 .or. isccp_top_height .eq. 3) then
511       meantb(1:npoints)=sum(boxttop,2)/ncol
512    else
513       meantb(1:npoints) = output_missing_value
514    endif
515
516    ! ####################################################################################
517    !                 Determines ISCCP cloud type frequencies
518    !
519    ! Now that boxptop and boxtau have been determined, determine amount of each of the
520    ! 49 ISCCP cloud types. Also compute grid box mean cloud top pressure and
521    ! optical thickness.  The mean cloud top pressure and optical thickness are
522    ! averages over the cloudy area only. The mean cloud top pressure is a linear
523    ! average of the cloud top pressures. The mean cloud optical thickness is
524    ! computed by converting optical thickness to an albedo, averaging in albedo
525    ! units, then converting the average albedo back to a mean optical thickness. 
526    ! ####################################################################################
527
528    ! Initialize
529    albedocld(1:npoints,1:ncol)  = 0._wp
530    box_cloudy(1:npoints,1:ncol) = .false.
531   
532    ! Reset frequencies
533    !fq_isccp = spread(spread(merge(0._wp,output_missing_value,sunlit .eq. 1 .or. isccp_top_height .eq. 3),2,7),2,7)
534    do ilev=1,7
535       do ilev2=1,7
536          do j=1,npoints !
537             if (sunlit(j).eq.1 .or. isccp_top_height .eq. 3) then
538                fq_isccp(j,ilev,ilev2)= 0.
539             else
540                fq_isccp(j,ilev,ilev2)= output_missing_value
541             end if
542          enddo
543       enddo
544    enddo
545
546   
547    ! Reset variables need for averaging cloud properties
548    where(sunlit .eq. 1 .or. isccp_top_height .eq. 3)
549       totalcldarea(1:npoints)  = 0._wp
550       meanalbedocld(1:npoints) = 0._wp
551       meanptop(1:npoints)      = 0._wp
552       meantaucld(1:npoints)    = 0._wp
553    elsewhere
554       totalcldarea(1:npoints)  = output_missing_value
555       meanalbedocld(1:npoints) = output_missing_value
556       meanptop(1:npoints)      = output_missing_value
557       meantaucld(1:npoints)    = output_missing_value
558    endwhere
559   
560    ! Compute column quantities and joint-histogram
561    do j=1,npoints
562       ! Subcolumns that are cloudy(true) and not(false)
563       box_cloudy2(1:ncol) = merge(.true.,.false.,boxtau(j,1:ncol) .gt. tauchk .and. boxptop(j,1:ncol) .gt. 0.)
564
565       ! Compute joint histogram and column quantities for points that are sunlit and cloudy
566       if (sunlit(j) .eq.1 .or. isccp_top_height .eq. 3) then
567          ! Joint-histogram
568          call hist2D(boxtau(j,1:ncol),boxptop(j,1:ncol),ncol,isccp_histTau,numISCCPTauBins, &
569               isccp_histPres,numISCCPPresBins,fq_isccp(j,1:numISCCPTauBins,1:numISCCPPresBins))
570          fq_isccp(j,1:numISCCPTauBins,1:numISCCPPresBins) = &
571               fq_isccp(j,1:numISCCPTauBins,1:numISCCPPresBins)/ncol
572         
573          ! Column cloud area
574          totalcldarea(j) = real(count(box_cloudy2(1:ncol) .and. boxtau(j,1:ncol) .gt. isccp_taumin))/ncol
575             
576          ! Subcolumn cloud albedo
577          !albedocld(j,1:ncol) = merge((boxtau(j,1:ncol)**0.895_wp)/((boxtau(j,1:ncol)**0.895_wp)+6.82_wp),&
578          !     0._wp,box_cloudy2(1:ncol) .and. boxtau(j,1:ncol) .gt. isccp_taumin)
579          where(box_cloudy2(1:ncol) .and. boxtau(j,1:ncol) .gt. isccp_taumin)
580             albedocld(j,1:ncol) = (boxtau(j,1:ncol)**0.895_wp)/((boxtau(j,1:ncol)**0.895_wp)+6.82_wp)
581          elsewhere
582             albedocld(j,1:ncol) = 0._wp
583          endwhere
584         
585          ! Column cloud albedo
586          meanalbedocld(j) = sum(albedocld(j,1:ncol))/ncol
587         
588          ! Column cloud top pressure
589          meanptop(j) = sum(boxptop(j,1:ncol),box_cloudy2(1:ncol) .and. boxtau(j,1:ncol) .gt. isccp_taumin)/ncol
590       endif
591    enddo
592   
593    ! Compute mean cloud properties. Set to mssing value in the event that totalcldarea=0
594    where(totalcldarea(1:npoints) .gt. 0)
595       meanptop(1:npoints)      = 100._wp*meanptop(1:npoints)/totalcldarea(1:npoints)
596       meanalbedocld(1:npoints) = meanalbedocld(1:npoints)/totalcldarea(1:npoints)
597       meantaucld(1:npoints)    = (6.82_wp/((1._wp/meanalbedocld(1:npoints))-1.))**(1._wp/0.895_wp)
598    elsewhere
599       meanptop(1:nPoints)      = output_missing_value
600       meanalbedocld(1:nPoints) = output_missing_value
601       meantaucld(1:nPoints)    = output_missing_value
602    endwhere
603    !meanptop(1:npoints)      = merge(100._wp*meanptop(1:npoints)/totalcldarea(1:npoints),&
604    !                                 output_missing_value,totalcldarea(1:npoints) .gt. 0)
605    !meanalbedocld(1:npoints) = merge(meanalbedocld(1:npoints)/totalcldarea(1:npoints), &
606    !                                 output_missing_value,totalcldarea(1:npoints) .gt. 0)
607    !meantaucld(1:npoints)    = merge((6.82_wp/((1._wp/meanalbedocld(1:npoints))-1.))**(1._wp/0.895_wp), &
608    !                                 output_missing_value,totalcldarea(1:npoints) .gt. 0)
609
610    ! Represent in percent
611    where(totalcldarea .ne. output_missing_value) totalcldarea = totalcldarea*100._wp
612    where(fq_isccp     .ne. output_missing_value) fq_isccp     = fq_isccp*100._wp
613   
614   
615  end SUBROUTINE ICARUS_column
616 
617  subroutine cosp_simulator_optics(dim1,dim2,dim3,flag,varIN1,varIN2,varOUT)
618    ! INPUTS
619    integer,intent(in) :: &
620         dim1,   & ! Dimension 1 extent (Horizontal)
621         dim2,   & ! Dimension 2 extent (Subcolumn)
622         dim3      ! Dimension 3 extent (Vertical)
623    real(wp),intent(in),dimension(dim1,dim2,dim3) :: &
624         flag      ! Logical to determine the of merge var1IN and var2IN
625    real(wp),intent(in),dimension(dim1,     dim3) :: &
626         varIN1, & ! Input field 1
627         varIN2    ! Input field 2
628    ! OUTPUTS
629    real(wp),intent(out),dimension(dim1,dim2,dim3) :: &
630         varOUT    ! Merged output field
631    ! LOCAL VARIABLES
632    integer :: j
633   
634    varOUT(1:dim1,1:dim2,1:dim3) = 0._wp
635    do j=1,dim2
636       where(flag(:,j,:) .eq. 1)
637          varOUT(:,j,:) = varIN2
638       endwhere
639       where(flag(:,j,:) .eq. 2)
640          varOUT(:,j,:) = varIN1
641       endwhere
642    enddo
643  end subroutine cosp_simulator_optics
644end module MOD_ICARUS
645
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