source: LMDZ6/branches/Amaury_dev/libf/phylmd/cosp/MISR_simulator.F @ 5119

Last change on this file since 5119 was 5099, checked in by abarral, 4 months ago

Replace most uses of CPP_DUST by the corresponding logical defined in lmdz_cppkeys_wrapper.F90
Convert several files from .F to .f90 to allow Dust to compile w/o rrtm/ecrad
Create lmdz_yoerad.f90
(lint) Remove "!" on otherwise empty line

  • Property copyright set to
    Name of program: LMDZ
    Creation date: 1984
    Version: LMDZ5
    License: CeCILL version 2
    Holder: Laboratoire de m\'et\'eorologie dynamique, CNRS, UMR 8539
    See the license file in the root directory
File size: 16.0 KB
Line 
1
2! Copyright (c) 2009,  Roger Marchand, version 1.2
3! All rights reserved.
4! $Revision: 23 $, $Date: 2011-03-31 15:41:37 +0200 (jeu. 31 mars 2011) $
5! $URL: http://cfmip-obs-sim.googlecode.com/svn/stable/v1.4.0/MISR_simulator/MISR_simulator.f $
6
7! Redistribution and use in source and binary forms, with or without modification, are permitted
8! provided that the following conditions are met:
9
10!     * Redistributions of source code must retain the above copyright notice, this list of
11!       conditions and the following disclaimer.
12!     * Redistributions in binary form must reproduce the above copyright notice, this list
13!       of conditions and the following disclaimer in the documentation and/or other materials
14!       provided with the distribution.
15!     * Neither the name of the University of Washington nor the names of its contributors may be used
16!       to endorse or promote products derived from this software without specific prior written permission.
17
18! THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING,
19! BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT
20! SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
21! DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
22! INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
23! NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
24
25      SUBROUTINE MISR_simulator(
26     &     npoints,
27     &     nlev,
28     &     ncol,
29     &     sunlit,
30     &     zfull,
31     &     at,
32     &     dtau_s,
33     &     dtau_c,
34     &     frac_out,
35     &     missing_value,
36     &     fq_MISR_TAU_v_CTH,
37     &     dist_model_layertops,
38     &     MISR_mean_ztop,
39     &     MISR_cldarea
40     & )
41   
42
43      implicit none
44      integer n_MISR_CTH
45      parameter(n_MISR_CTH=16)
46         
47!     -----
48!     Input
49!     -----
50
51      INTEGER npoints                   !  if ncol ==1, the number of model points in the horizontal grid 
52                            !   else    the number of GCM grid points
53                           
54      INTEGER nlev                      !  number of model vertical levels
55     
56      INTEGER ncol                      !  number of model sub columns
57                        !  (must already be generated in via scops and passed to this
58                        !   routine via the variable frac_out )
59 
60      INTEGER sunlit(npoints)           !  1 for day points, 0 for night time
61
62      REAL zfull(npoints,nlev)          !  height (in meters) of full model levels (i.e. midpoints)
63                                        !  zfull(npoints,1)    is    top level of model
64                                        !  zfull(npoints,nlev) is bottom level of model (closest point to surface) 
65
66      REAL at(npoints,nlev)             !  temperature in each model level (K)
67 
68      REAL dtau_s(npoints,nlev)         !  visible wavelength cloud optical depth ... for "stratiform" condensate
69                                        !  NOTE:  this the cloud optical depth of only the
70                    !     the model cell (i,j)
71                   
72      REAL dtau_c(npoints,nlev)         !  visible wavelength cloud optical depth ... for "convective" condensate
73                                        !  NOTE:  this the cloud optical depth of only the
74                    !     the model cell (i,j)
75                                     
76      REAL frac_out(npoints,ncol,nlev)  !  NOTE: only need if columns>1 ... subgrid scheme in use.
77     
78      REAL missing_value
79                                 
80!     ------
81!     Outputs
82!     ------
83           
84      REAL fq_MISR_TAU_v_CTH(npoints,7,n_MISR_CTH)     
85      REAL dist_model_layertops(npoints,n_MISR_CTH)
86      REAL MISR_cldarea(npoints)               ! fractional area coverged by clouds
87      REAL MISR_mean_ztop(npoints)             ! mean cloud top hieght(m) MISR would observe
88                                   ! NOTE: == 0 if area ==0
89                           
90
91!     ------
92!     Working variables
93!     ------
94
95      REAL tau(npoints,ncol)        ! total column optical depth ...
96
97      INTEGER j,ilev,ilev2,ibox,k
98      INTEGER itau
99         
100      LOGICAL box_cloudy(npoints,ncol)
101     
102      real isccp_taumin
103      real boxarea
104      real tauchk
105      REAL box_MISR_ztop(npoints,ncol)  ! cloud top hieght(m) MISR would observe
106     
107      integer thres_crossed_MISR
108      integer loop,iMISR_ztop
109     
110      real dtau, cloud_dtau, MISR_penetration_height,ztest     
111     
112      real MISR_CTH_boundaries(n_MISR_CTH+1)
113     
114      DATA MISR_CTH_boundaries / -99, 0, 0.5, 1, 1.5, 2, 2.5, 3,
115     c                    4, 5, 7, 9, 11, 13, 15, 17, 99 /
116     
117      DATA isccp_taumin / 0.3 /
118   
119      tauchk = -1.*log(0.9999999)
120
121      ! For each GCM cell or horizontal model grid point ...
122
123      do j=1,npoints   
124
125         !  estimate distribution of Model layer tops
126
127         dist_model_layertops(j,:)=0
128
129       do ilev=1,nlev
130           
131        ! define location of "layer top"
132        if(ilev.eq.1 .or. ilev.eq.nlev) then
133            ztest=zfull(j,ilev)
134        else
135            ztest=0.5*(zfull(j,ilev)+zfull(j,ilev-1))
136        endif   
137
138        ! find MISR layer that contains this level
139        ! note, the first MISR level is "no height" level
140        iMISR_ztop=2
141        do loop=2,n_MISR_CTH
142       
143            if ( ztest .gt.
144     &                1000*MISR_CTH_boundaries(loop+1) ) then
145       
146                iMISR_ztop=loop+1
147            endif
148        enddo
149
150        dist_model_layertops(j,iMISR_ztop)=
151     &          dist_model_layertops(j,iMISR_ztop)+1
152       enddo
153
154         ! compute total cloud optical depth for each column
155
156       do ibox=1,ncol     
157       
158        ! Initialize tau to zero in each subcolum
159            tau(j,ibox)=0.
160        box_cloudy(j,ibox)=.false.
161        box_MISR_ztop(j,ibox)=0 
162       
163        ! initialize threshold detection for each sub column
164        thres_crossed_MISR=0;
165       
166        do ilev=1,nlev
167     
168             dtau=0
169             
170             if (frac_out(j,ibox,ilev).eq.1) then
171                        dtau = dtau_s(j,ilev)
172                 endif
173                 
174                 if (frac_out(j,ibox,ilev).eq.2) then
175                        dtau = dtau_c(j,ilev)
176                 end if
177                 
178             tau(j,ibox)=tau(j,ibox)+ dtau
179             
180                     
181        ! NOW for MISR ..
182        ! if there a cloud ... start the counter ... store this height
183        if(thres_crossed_MISR .eq. 0 .and. dtau .gt. 0.) then
184       
185            ! first encountered a "cloud"
186            thres_crossed_MISR=1 
187            cloud_dtau=0           
188        endif   
189               
190        if( thres_crossed_MISR .lt. 99 .and.
191     &              thres_crossed_MISR .gt. 0 ) then
192     
193                if( dtau .eq. 0.) then
194       
195                    ! we have come to the end of the current cloud
196                ! layer without yet selecting a CTH boundary.
197                ! ... restart cloud tau counter
198                cloud_dtau=0
199            else
200                ! add current optical depth to count for
201                ! the current cloud layer
202                cloud_dtau=cloud_dtau+dtau
203            endif
204               
205            ! if the cloud is continuous but optically thin (< 1)
206            ! from above the current layer cloud top to the current level
207            ! then MISR will like see a top below the top of the current
208            ! layer
209            if( dtau.gt.0 .and. (cloud_dtau-dtau) .lt. 1) then
210           
211                if(dtau .lt. 1 .or. ilev.eq.1 .or. ilev.eq.nlev) then
212
213                    ! MISR will likely penetrate to some point
214                    ! within this layer ... the middle
215                    MISR_penetration_height=zfull(j,ilev)
216
217                else
218                    ! take the OD = 1.0 level into this layer
219                    MISR_penetration_height=
220     &                     0.5*(zfull(j,ilev)+zfull(j,ilev-1)) -
221     &                     0.5*(zfull(j,ilev-1)-zfull(j,ilev+1))
222     &                  /dtau
223                endif   
224
225                box_MISR_ztop(j,ibox)=MISR_penetration_height
226               
227            endif
228       
229            ! check for a distinctive water layer
230            if(dtau .gt. 1 .and. at(j,ilev).gt.273 ) then
231     
232                    ! must be a water cloud ...
233                ! take this as CTH level
234                thres_crossed_MISR=99
235            endif
236       
237            ! if the total column optical depth is "large" than
238            ! MISR can't seen anything else ... set current point as CTH level
239            if(tau(j,ibox) .gt. 5) then
240
241                thres_crossed_MISR=99           
242            endif
243
244        endif ! MISR CTH booundary not set
245       
246        enddo  !ilev - loop over vertical levesl
247   
248        ! written by roj 5/2006
249        ! check to see if there was a cloud for which we didn't
250        ! set a MISR cloud top boundary
251        if( thres_crossed_MISR .eq. 1) then
252   
253        ! if the cloud has a total optical depth of greater
254        ! than ~ 0.5 MISR will still likely pick up this cloud
255        ! with a height near the true cloud top
256        ! otherwise there should be no CTH
257        if( tau(j,ibox) .gt. 0.5) then
258
259            ! keep MISR detected CTH
260           
261        elseif(tau(j,ibox) .gt. 0.2) then
262
263            ! MISR may detect but wont likley have a good height
264            box_MISR_ztop(j,ibox)=-1
265           
266        else
267            ! MISR not likely to even detect.
268            ! so set as not cloudy
269            box_MISR_ztop(j,ibox)=0
270
271        endif
272                       
273        endif
274   
275       enddo  ! loop of subcolumns
276       enddo    ! loop of gridpoints
277
278        !   Modify MISR CTH for satellite spatial / pattern matcher effects
279
280    !   Code in this region added by roj 5/2006 to account
281    !   for spatial effect of the MISR pattern matcher.
282    !   Basically, if a column is found between two neighbors
283    !   at the same CTH, and that column has no hieght or
284    !   a lower CTH, THEN misr will tend to but place the
285    !   odd column at the same height as it neighbors.
286
287    !   This setup assumes the columns represent a about a 1 to 4 km scale
288    !   it will need to be modified significantly, otherwise
289        if(ncol.eq.1) then
290   
291       ! adjust based on neightboring points ... i.e. only 2D grid was input
292           do j=2,npoints-1
293           
294            if(box_MISR_ztop(j-1,1).gt.0 .and.
295     &             box_MISR_ztop(j+1,1).gt.0       ) then
296
297                if( abs( box_MISR_ztop(j-1,1) - 
298     &                   box_MISR_ztop(j+1,1) ) .lt. 500
299     &              .and.
300     &                   box_MISR_ztop(j,1) .lt.
301     &                   box_MISR_ztop(j+1,1)     ) then
302           
303                    box_MISR_ztop(j,1) =
304     &                      box_MISR_ztop(j+1,1)   
305                endif
306
307            endif
308         enddo
309        else
310         
311         ! adjust based on neighboring subcolumns ....
312         do ibox=2,ncol-1
313           
314            if(box_MISR_ztop(1,ibox-1).gt.0 .and.
315     &             box_MISR_ztop(1,ibox+1).gt.0        ) then
316
317                if( abs( box_MISR_ztop(1,ibox-1) - 
318     &                   box_MISR_ztop(1,ibox+1) ) .lt. 500
319     &              .and.
320     &                   box_MISR_ztop(1,ibox) .lt.
321     &                   box_MISR_ztop(1,ibox+1)     ) then
322           
323                    box_MISR_ztop(1,ibox) =
324     &                      box_MISR_ztop(1,ibox+1)   
325                endif
326
327            endif
328         enddo
329     
330        endif
331
332    !     DETERMINE CLOUD TYPE FREQUENCIES
333
334    !     Now that ztop and tau have been determined,
335    !     determine amount of each cloud type
336        boxarea=1./real(ncol) 
337        do j=1,npoints
338
339         ! reset frequencies -- modified loop structure, roj 5/2006
340         do ilev=1,7  ! "tau loop" 
341            do  ilev2=1,n_MISR_CTH                     
342            fq_MISR_TAU_v_CTH(j,ilev,ilev2)=0.     
343            enddo
344         enddo
345           
346         MISR_cldarea(j)=0.
347         MISR_mean_ztop(j)=0.
348
349         do ibox=1,ncol
350
351            if (tau(j,ibox) .gt. (tauchk)) then
352               box_cloudy(j,ibox)=.true.
353            endif
354 
355            itau = 0
356       
357            if (box_cloudy(j,ibox)) then
358   
359          !determine optical depth category
360              if (tau(j,ibox) .lt. isccp_taumin) then
361                  itau=1
362              else if (tau(j,ibox) .ge. isccp_taumin                                   
363     &          .and. tau(j,ibox) .lt. 1.3) then
364                  itau=2
365              else if (tau(j,ibox) .ge. 1.3
366     &          .and. tau(j,ibox) .lt. 3.6) then
367                  itau=3
368              else if (tau(j,ibox) .ge. 3.6
369     &          .and. tau(j,ibox) .lt. 9.4) then
370                  itau=4
371              else if (tau(j,ibox) .ge. 9.4
372     &          .and. tau(j,ibox) .lt. 23.) then
373                  itau=5
374              else if (tau(j,ibox) .ge. 23.
375     &          .and. tau(j,ibox) .lt. 60.) then
376                  itau=6
377              else if (tau(j,ibox) .ge. 60.) then
378                  itau=7
379              endif
380             
381             endif 
382
383       ! update MISR histograms and summary metrics - roj 5/2005
384       if (sunlit(j).eq.1) then
385                     
386              !if cloudy added by roj 5/2005
387          if( box_MISR_ztop(j,ibox).eq.0) then
388         
389            ! no cloud detected
390            iMISR_ztop=0
391
392          elseif( box_MISR_ztop(j,ibox).eq.-1) then
393
394            ! cloud can be detected but too thin to get CTH
395            iMISR_ztop=1   
396
397            fq_MISR_TAU_v_CTH(j,itau,iMISR_ztop)=
398     &            fq_MISR_TAU_v_CTH(j,itau,iMISR_ztop) + boxarea
399
400          else
401
402            ! determine index for MISR bin set
403
404            iMISR_ztop=2
405           
406            do loop=2,n_MISR_CTH
407       
408                if ( box_MISR_ztop(j,ibox) .gt.
409     &                1000*MISR_CTH_boundaries(loop+1) ) then
410       
411                  iMISR_ztop=loop+1
412
413                endif
414            enddo
415         
416            if(box_cloudy(j,ibox)) then
417           
418               ! there is an isccp clouds so itau(j) is defined
419               fq_MISR_TAU_v_CTH(j,itau,iMISR_ztop)=
420     &            fq_MISR_TAU_v_CTH(j,itau,iMISR_ztop) + boxarea
421     
422            else
423                ! MISR CTH resolution is trying to fill in a
424                ! broken cloud scene where there is no condensate.
425                ! The MISR CTH-1D-OD product will only put in a cloud
426                ! if the MISR cloud mask indicates cloud.
427                ! therefore we will not include this column in the histogram
428                ! in reality aerosoal and 3D effects or bright surfaces
429                ! could fool the MISR cloud mask
430
431                ! the alternative is to count as very thin cloud ??
432!               fq_MISR_TAU_v_CTH(1,iMISR_ztop)=
433!     &                     fq_MISR_TAU_v_CTH(1,iMISR_ztop) + boxarea
434            endif
435
436
437            MISR_mean_ztop(j)=MISR_mean_ztop(j)+
438     &                       box_MISR_ztop(j,ibox)*boxarea         
439
440            MISR_cldarea(j)=MISR_cldarea(j) + boxarea
441 
442          endif
443       else
444          ! Set to issing data. A. Bodas - 14/05/2010
445          do loop=1,n_MISR_CTH
446             do k=1,7
447                fq_MISR_TAU_v_CTH(j,k,loop) = missing_value
448             enddo
449             dist_model_layertops(j,loop) = missing_value
450          enddo
451          MISR_cldarea(j) = missing_value
452          MISR_mean_ztop(npoints) = missing_value
453
454       endif ! is sunlight ?
455       
456       enddo ! ibox - loop over subcolumns         
457     
458       if( MISR_cldarea(j) .gt. 0.) then
459        MISR_mean_ztop(j)= MISR_mean_ztop(j) / MISR_cldarea(j)   ! roj 5/2006
460       endif
461
462       enddo  ! loop over grid points
463
464      return
465      end
Note: See TracBrowser for help on using the repository browser.