source: LMDZ6/trunk/libf/phylmd/cosp/scops.f90 @ 5407

Last change on this file since 5407 was 5248, checked in by abarral, 8 weeks ago

(cont.) Convert fixed-form to free-form sources .F -> .{f,F}90

  • 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: 10.4 KB
Line 
1subroutine scops(npoints,nlev,ncol,seed,cc,conv, &
2        overlap,frac_out,ncolprint)
3
4
5  ! *****************************COPYRIGHT****************************
6  ! (c) British Crown Copyright 2009, the Met Office.
7  ! All rights reserved.
8  ! $Revision: 23 $, $Date: 2011-03-31 15:41:37 +0200 (jeu. 31 mars 2011) $
9  ! $URL: http://cfmip-obs-sim.googlecode.com/svn/stable/v1.4.0/icarus-scops-4.1-bsd/scops.f $
10  !
11  ! Redistribution and use in source and binary forms, with or without
12  ! modification, are permitted provided that the
13  ! following conditions are met:
14  !
15  ! * Redistributions of source code must retain the above
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18  ! * Redistributions in binary form must reproduce the above
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20  !   disclaimer in the documentation and/or other materials
21  !   provided with the distribution.
22  ! * Neither the name of the Met Office nor the names of its
23  !   contributors may be used to endorse or promote products
24  !   derived from this software without specific prior written
25  !   permission.
26  !
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29  ! LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
30  ! A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
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32  ! SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
33  ! LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
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37  ! OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
38  !
39  ! *****************************COPYRIGHT*******************************
40  ! *****************************COPYRIGHT*******************************
41  ! *****************************COPYRIGHT*******************************
42
43  implicit none
44
45  INTEGER :: npoints       !  number of model points in the horizontal
46  INTEGER :: nlev          !  number of model levels in column
47  INTEGER :: ncol          !  number of subcolumns
48
49
50  INTEGER :: overlap         !  overlap type
51                          ! !  1=max
52                          ! !  2=rand
53                          ! !  3=max/rand
54  REAL :: cc(npoints,nlev)
55              ! !  input cloud cover in each model level (fraction)
56              ! !  NOTE:  This is the HORIZONTAL area of each
57              ! !         grid box covered by clouds
58
59  REAL :: conv(npoints,nlev)
60              ! !  input convective cloud cover in each model
61              ! !   level (fraction)
62              ! !  NOTE:  This is the HORIZONTAL area of each
63              ! !         grid box covered by convective clouds
64
65  INTEGER :: i,j,ilev,ibox,ncolprint,ilev2
66
67  REAL :: frac_out(npoints,ncol,nlev) ! boxes gridbox divided up into
68                          ! ! Equivalent of BOX in original version, but
69                          ! ! indexed by column then row, rather than
70                          ! ! by row then column
71
72
73  INTEGER :: seed(npoints)
74  ! !  seed values for marsaglia  random number generator
75  ! !  It is recommended that the seed is set
76  ! !  to a different value for each model
77  ! !  gridbox it is called on, as it is
78  ! !  possible that the choice of the same
79  ! !  seed value every time may introduce some
80  ! !  statistical bias in the results, particularly
81  ! !  for low values of NCOL.
82
83  REAL :: tca(npoints,0:nlev) ! total cloud cover in each model level (fraction)
84                                    ! ! with extra layer of zeroes on top
85                                    ! ! in this version this just contains the values input
86                                    ! ! from cc but with an extra level
87
88  REAL :: threshold(npoints,ncol)   ! pointer to position in gridbox
89  REAL :: maxocc(npoints,ncol)      ! Flag for max overlapped conv cld
90  REAL :: maxosc(npoints,ncol)      ! Flag for max overlapped strat cld
91
92  REAL :: boxpos(npoints,ncol)      ! ordered pointer to position in gridbox
93
94  REAL :: threshold_min(npoints,ncol) ! minimum value to define range in with new threshold
95                                    ! ! is chosen
96
97  REAL :: ran(npoints)                 ! vector of random numbers
98
99  INTEGER :: irand,i2_16,huge32,overflow_32  ! variables for RNG
100  PARAMETER(huge32=2147483647)
101  i2_16=65536
102
103  do ibox=1,ncol
104    do j=1,npoints
105    boxpos(j,ibox)=(ibox-.5)/ncol
106    enddo
107  enddo
108
109  ! ---------------------------------------------------!
110  ! Initialise working variables
111  ! ---------------------------------------------------!
112
113  ! Initialised frac_out to zero
114
115  do ilev=1,nlev
116    do ibox=1,ncol
117      do j=1,npoints
118      frac_out(j,ibox,ilev)=0.0
119      enddo
120    enddo
121  enddo
122
123  ! assign 2d tca array using 1d input array cc
124
125  do j=1,npoints
126    tca(j,0)=0
127  enddo
128
129  do ilev=1,nlev
130    do j=1,npoints
131      tca(j,ilev)=cc(j,ilev)
132    enddo
133  enddo
134
135  if (ncolprint.ne.0) then
136    write (6,'(a)') 'frac_out_pp_rev:'
137      do j=1,npoints,1000
138      write(6,'(a10)') 'j='
139      write(6,'(8I10)') j
140      write (6,'(8f5.2)') &
141            ((frac_out(j,ibox,ilev),ibox=1,ncolprint),ilev=1,nlev)
142
143      enddo
144    write (6,'(a)') 'ncol:'
145    write (6,'(I3)') ncol
146  endif
147  if (ncolprint.ne.0) then
148    write (6,'(a)') 'last_frac_pp:'
149      do j=1,npoints,1000
150      write(6,'(a10)') 'j='
151      write(6,'(8I10)') j
152      write (6,'(8f5.2)') (tca(j,0))
153      enddo
154  endif
155
156  ! ---------------------------------------------------!
157  ! ALLOCATE CLOUD INTO BOXES, FOR NCOLUMNS, NLEVELS
158  ! frac_out is the array that contains the information
159  ! where 0 is no cloud, 1 is a stratiform cloud and 2 is a
160  ! convective cloud
161
162  ! !loop over vertical levels
163  DO ilev = 1,nlev
164
165  ! Initialise threshold
166
167    IF (ilev.eq.1) then
168      ! ! If max overlap
169      IF (overlap.eq.1) then
170        ! ! select pixels spread evenly
171        ! ! across the gridbox
172          DO ibox=1,ncol
173            do j=1,npoints
174              threshold(j,ibox)=boxpos(j,ibox)
175            enddo
176          enddo
177      ELSE
178          DO ibox=1,ncol
179            include 'congvec.h'
180            ! ! select random pixels from the non-convective
181            ! ! part the gridbox ( some will be converted into
182            ! ! convective pixels below )
183            do j=1,npoints
184              threshold(j,ibox)= &
185                    conv(j,ilev)+(1-conv(j,ilev))*ran(j)
186            enddo
187          enddo
188        ENDIF
189        IF (ncolprint.ne.0) then
190          write (6,'(a)') 'threshold_nsf2:'
191            do j=1,npoints,1000
192            write(6,'(a10)') 'j='
193            write(6,'(8I10)') j
194            write (6,'(8f5.2)') (threshold(j,ibox),ibox=1,ncolprint)
195            enddo
196        ENDIF
197    ENDIF
198
199    IF (ncolprint.ne.0) then
200        write (6,'(a)') 'ilev:'
201        write (6,'(I2)') ilev
202    ENDIF
203
204    DO ibox=1,ncol
205
206      ! ! All versions
207      do j=1,npoints
208        if (boxpos(j,ibox).le.conv(j,ilev)) then
209          maxocc(j,ibox) = 1
210        else
211          maxocc(j,ibox) = 0
212        end if
213      enddo
214
215      ! ! Max overlap
216      if (overlap.eq.1) then
217        do j=1,npoints
218          threshold_min(j,ibox)=conv(j,ilev)
219          maxosc(j,ibox)=1
220        enddo
221      endif
222
223      ! ! Random overlap
224      if (overlap.eq.2) then
225        do j=1,npoints
226          threshold_min(j,ibox)=conv(j,ilev)
227          maxosc(j,ibox)=0
228        enddo
229      endif
230
231      ! ! Max/Random overlap
232      if (overlap.eq.3) then
233        do j=1,npoints
234          threshold_min(j,ibox)=max(conv(j,ilev), &
235                min(tca(j,ilev-1),tca(j,ilev)))
236          if (threshold(j,ibox) &
237                .lt.min(tca(j,ilev-1),tca(j,ilev)) &
238                .and.(threshold(j,ibox).gt.conv(j,ilev))) then
239               maxosc(j,ibox)= 1
240          else
241               maxosc(j,ibox)= 0
242          end if
243        enddo
244      endif
245
246      ! ! Reset threshold
247
248      include 'congvec.h'
249
250      do j=1,npoints
251        threshold(j,ibox)= &
252          ! !if max overlapped conv cloud
253              maxocc(j,ibox) * ( &
254              boxpos(j,ibox) &
255              ) + &
256          ! !else
257              (1-maxocc(j,ibox)) * ( &
258              ! !if max overlapped strat cloud
259              (maxosc(j,ibox)) * ( &
260                  ! !threshold=boxpos
261              threshold(j,ibox) &
262              ) + &
263              ! !else
264              (1-maxosc(j,ibox)) * ( &
265                  ! !threshold_min=random[thrmin,1]
266              threshold_min(j,ibox)+ &
267              (1-threshold_min(j,ibox))*ran(j) &
268              ) &
269              )
270      enddo
271
272    ENDDO ! ibox
273
274       ! Fill frac_out with 1's where tca is greater than the threshold
275
276       DO ibox=1,ncol
277         do j=1,npoints
278           if (tca(j,ilev).gt.threshold(j,ibox)) then
279           frac_out(j,ibox,ilev)=1
280           else
281           frac_out(j,ibox,ilev)=0
282           end if
283         enddo
284       ENDDO
285
286      ! Code to partition boxes into startiform and convective parts
287      ! goes here
288
289       DO ibox=1,ncol
290         do j=1,npoints
291            if (threshold(j,ibox).le.conv(j,ilev)) then
292                ! ! = 2 IF threshold le conv(j)
293                frac_out(j,ibox,ilev) = 2
294            else
295                ! ! = the same IF NOT threshold le conv(j)
296                frac_out(j,ibox,ilev) = frac_out(j,ibox,ilev)
297            end if
298         enddo
299       ENDDO
300
301      ! Set last_frac to tca at this level, so as to be tca
302      ! from last level next time round
303
304      if (ncolprint.ne.0) then
305
306        do j=1,npoints ,1000
307        write(6,'(a10)') 'j='
308        write(6,'(8I10)') j
309        write (6,'(a)') 'last_frac:'
310        write (6,'(8f5.2)') (tca(j,ilev-1))
311
312        write (6,'(a)') 'conv:'
313        write (6,'(8f5.2)') (conv(j,ilev),ibox=1,ncolprint)
314
315        write (6,'(a)') 'max_overlap_cc:'
316        write (6,'(8f5.2)') (maxocc(j,ibox),ibox=1,ncolprint)
317
318        write (6,'(a)') 'max_overlap_sc:'
319        write (6,'(8f5.2)') (maxosc(j,ibox),ibox=1,ncolprint)
320
321        write (6,'(a)') 'threshold_min_nsf2:'
322        write (6,'(8f5.2)') (threshold_min(j,ibox),ibox=1,ncolprint)
323
324        write (6,'(a)') 'threshold_nsf2:'
325        write (6,'(8f5.2)') (threshold(j,ibox),ibox=1,ncolprint)
326
327        write (6,'(a)') 'frac_out_pp_rev:'
328        write (6,'(8f5.2)') &
329              ((frac_out(j,ibox,ilev2),ibox=1,ncolprint),ilev2=1,nlev)
330      enddo
331      endif
332
333  END DO
334
335
336end subroutine scops
337
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