source: LMDZ5/branches/IPSLCM5A2.1/libf/phylmd/grid_noro_m.F90 @ 5394

Last change on this file since 5394 was 2576, checked in by dcugnet, 8 years ago

Use "traditional" sst/sic files without additional records from contiguous years,
but check for previous and next files. Example for Amip Sea Surface Temperature:

  • amipbc_sst_1x1.nc must be present.
  • if amipbc_sst_1x1_m.nc is present (previous year), its last record is used

for interpolation ; otherwise, the last record of amipbc_sst_1x1.nc is used.

  • if amipbc_sst_1x1_p.nc is present (next year), its first record is used

for interpolation ; otherwise, the first record of amipbc_sst_1x1.nc is used.
If both contiguous fiels are missing, the interpolation then implies periodicity.
Note: grid_noro0 has been moved from limit_netcd to grid_noro_m where it belongs.

File size: 20.6 KB
Line 
1MODULE grid_noro_m
2!
3!*******************************************************************************
4
5  USE print_control_mod, ONLY: lunout
6  USE assert_eq_m,       ONLY: assert_eq
7  PRIVATE
8  PUBLIC :: grid_noro, grid_noro0
9
10
11CONTAINS
12
13
14!-------------------------------------------------------------------------------
15!
16SUBROUTINE grid_noro(xd,yd,zd,x,y,zphi,zmea,zstd,zsig,zgam,zthe,zpic,zval,mask)
17!
18!-------------------------------------------------------------------------------
19! Author: F. Lott (see also Z.X. Li, A. Harzallah et L. Fairhead)
20!-------------------------------------------------------------------------------
21! Purpose: Compute the Parameters of the SSO scheme as described in LOTT &MILLER
22!         (1997) and LOTT(1999).
23!-------------------------------------------------------------------------------
24! Comments:
25!  * Target points are on a rectangular grid:
26!      iim+1 latitudes including North and South Poles;
27!      jjm+1 longitudes, with periodicity jjm+1=1.
28!  * At the poles, the fields value is repeated jjm+1 time.
29!  * The parameters a,b,c,d represent the limits of the target gridpoint region.
30!    The means over this region are calculated from USN data, ponderated by a
31!    weight proportional to the surface occupated by the data inside the model
32!    gridpoint area. In most circumstances, this weight is the ratio between the
33!    surfaces of the USN gridpoint area and the model gridpoint area.
34!
35!           (c)
36!        ----d-----
37!        | . . . .|
38!        |        |
39!     (b)a . * . .b(a)
40!        |        |
41!        | . . . .|
42!        ----c-----
43!           (d)
44!  * Hard-coded US Navy dataset dimensions (imdp=2160 ; jmdp=1080) have been
45!    removed (ALLOCATABLE used).
46!  * iext (currently 10% of imdp) represents the margin to ensure output cells
47!    on the edge are contained in input cells.
48!===============================================================================
49  IMPLICIT NONE
50!-------------------------------------------------------------------------------
51! Arguments:
52  REAL, INTENT(IN)  :: xd(:), yd(:)  !--- INPUT  COORDINATES     (imdp) (jmdp)
53  REAL, INTENT(IN)  :: zd(:,:)       !--- INPUT  FIELD           (imdp,jmdp)
54  REAL, INTENT(IN)  :: x(:), y(:)    !--- OUTPUT COORDINATES     (imar+1) (jmar)
55  REAL, INTENT(OUT) :: zphi(:,:)     !--- GEOPOTENTIAL           (imar+1,jmar)
56  REAL, INTENT(OUT) :: zmea(:,:)     !--- MEAN OROGRAPHY         (imar+1,jmar)
57  REAL, INTENT(OUT) :: zstd(:,:)     !--- STANDARD DEVIATION     (imar+1,jmar)
58  REAL, INTENT(OUT) :: zsig(:,:)     !--- SLOPE                  (imar+1,jmar)
59  REAL, INTENT(OUT) :: zgam(:,:)     !--- ANISOTROPY             (imar+1,jmar)
60  REAL, INTENT(OUT) :: zthe(:,:)     !--- SMALL AXIS ORIENTATION (imar+1,jmar)
61  REAL, INTENT(OUT) :: zpic(:,:)     !--- MAXIMUM ALTITITUDE     (imar+1,jmar)
62  REAL, INTENT(OUT) :: zval(:,:)     !--- MINIMUM ALTITITUDE     (imar+1,jmar)
63  REAL, INTENT(OUT) :: mask(:,:)     !--- MASK                   (imar+1,jmar)
64!-------------------------------------------------------------------------------
65! Local variables:
66  CHARACTER(LEN=256) :: modname="grid_noro"
67  REAL, ALLOCATABLE :: xusn(:), yusn(:)           ! dim (imdp+2*iext) (jmdp+2)
68  REAL, ALLOCATABLE :: zusn(:,:)                  ! dim (imdp+2*iext,jmdp+2)
69! CORRELATIONS OF OROGRAPHY GRADIENT              ! dim (imar+1,jmar)
70  REAL, ALLOCATABLE :: ztz(:,:), zxtzx(:,:), zytzy(:,:), zxtzy(:,:), weight(:,:)
71! CORRELATIONS OF USN OROGRAPHY GRADIENTS         ! dim (imar+2*iext,jmdp+2)
72  REAL, ALLOCATABLE :: zxtzxusn(:,:), zytzyusn(:,:), zxtzyusn(:,:)
73  REAL, ALLOCATABLE :: mask_tmp(:,:), zmea0(:,:)  ! dim (imar+1,jmar)
74  REAL, ALLOCATABLE :: num_tot(:,:), num_lan(:,:) ! dim (imax,jmax)
75  REAL, ALLOCATABLE :: a(:), b(:)                 ! dim (imax)
76  REAL, ALLOCATABLE :: c(:), d(:)                 ! dim (jmax)
77  LOGICAL :: masque_lu
78  INTEGER :: i, ii, imdp, imar, iext
79  INTEGER :: j, jj, jmdp, jmar, nn
80  REAL    :: xpi, zdeltax, zlenx, weighx, xincr,  zmeanor0
81  REAL    :: rad, zdeltay, zleny, weighy, masque, zmeasud0
82  REAL    :: zbordnor, zmeanor, zstdnor, zsignor, zweinor, zpicnor, zvalnor
83  REAL    :: zbordsud, zmeasud, zstdsud, zsigsud, zweisud, zpicsud, zvalsud
84  REAL    :: zbordest, zbordoue, xk, xl, xm, xp, xq, xw
85!-------------------------------------------------------------------------------
86  imdp=assert_eq(SIZE(xd),SIZE(zd,1),TRIM(modname)//" imdp")
87  jmdp=assert_eq(SIZE(yd),SIZE(zd,2),TRIM(modname)//" jmdp")
88  imar=assert_eq([SIZE(x),SIZE(zphi,1),SIZE(zmea,1),SIZE(zstd,1),SIZE(zsig,1), &
89                          SIZE(zgam,1),SIZE(zthe,1),SIZE(zpic,1),SIZE(zval,1), &
90                          SIZE(mask,1)],TRIM(modname)//" imar")-1
91  jmar=assert_eq([SIZE(y),SIZE(zphi,2),SIZE(zmea,2),SIZE(zstd,2),SIZE(zsig,2), &
92                          SIZE(zgam,2),SIZE(zthe,2),SIZE(zpic,2),SIZE(zval,2), &
93                          SIZE(mask,2)],TRIM(modname)//" jmar")
94!  IF(imar/=iim)   CALL abort_physic(TRIM(modname),'imar/=iim'  ,1)
95!  IF(jmar/=jjm+1) CALL abort_physic(TRIM(modname),'jmar/=jjm+1',1)
96  iext=imdp/10                                !--- OK up to 36 degrees cell
97  xpi = ACOS(-1.)
98  rad = 6371229.
99  zdeltay=2.*xpi/REAL(jmdp)*rad
100  WRITE(lunout,*)"*** Orography parameters at sub-cell scale ***"
101
102!--- ARE WE USING A READ MASK ?
103  masque_lu=ANY(mask/=-99999.); IF(.NOT.masque_lu) mask=0.0
104  WRITE(lunout,*)'Masque lu: ',masque_lu
105
106!--- EXTENSION OF THE INPUT DATABASE TO PROCEED COMPUTATIONS AT BOUNDARIES:
107  ALLOCATE(xusn(imdp+2*iext))
108  xusn(1     +iext:imdp  +iext)=xd(:)
109  xusn(1          :       iext)=xd(1+imdp-iext:imdp)-2.*xpi
110  xusn(1+imdp+iext:imdp+2*iext)=xd(1          :iext)+2.*xpi
111
112  ALLOCATE(yusn(jmdp+2))
113  yusn(1       )=yd(1)   +(yd(1)   -yd(2))
114  yusn(2:jmdp+1)=yd(:)
115  yusn(  jmdp+2)=yd(jmdp)+(yd(jmdp)-yd(jmdp-1))
116
117  ALLOCATE(zusn(imdp+2*iext,jmdp+2))
118  zusn(1       +iext:imdp  +iext,2:jmdp+1)=zd  (:                   ,     :)
119  zusn(1            :       iext,2:jmdp+1)=zd  (imdp-iext+1:imdp    ,     :)
120  zusn(1+imdp  +iext:imdp+2*iext,2:jmdp+1)=zd  (1:iext              ,     :)
121  zusn(1            :imdp/2+iext,       1)=zusn(1+imdp/2:imdp  +iext,     2)
122  zusn(1+imdp/2+iext:imdp+2*iext,       1)=zusn(1       :imdp/2+iext,     2)
123  zusn(1            :imdp/2+iext,  jmdp+2)=zusn(1+imdp/2:imdp  +iext,jmdp+1)
124  zusn(1+imdp/2+iext:imdp+2*iext,  jmdp+2)=zusn(1       :imdp/2+iext,jmdp+1)
125
126!--- COMPUTE LIMITS OF MODEL GRIDPOINT AREA (REGULAR GRID)
127  ALLOCATE(a(imar+1),b(imar+1))
128  b(1:imar)=(x(1:imar  )+ x(2:imar+1))/2.0
129  b(imar+1)= x(  imar+1)+(x(  imar+1)-x(imar))/2.0
130  a(1)=x(1)-(x(2)-x(1))/2.0
131  a(2:imar+1)= b(1:imar)
132
133  ALLOCATE(c(jmar),d(jmar))
134  d(1:jmar-1)=(y(1:jmar-1)+ y(2:jmar))/2.0
135  d(  jmar  )= y(  jmar  )+(y(  jmar)-y(jmar-1))/2.0
136  c(1)=y(1)-(y(2)-y(1))/2.0
137  c(2:jmar)=d(1:jmar-1)
138
139!--- INITIALIZATIONS:
140  ALLOCATE(weight(imar+1,jmar)); weight(:,:)= 0.0
141  ALLOCATE(zxtzx (imar+1,jmar)); zxtzx (:,:)= 0.0
142  ALLOCATE(zytzy (imar+1,jmar)); zytzy (:,:)= 0.0
143  ALLOCATE(zxtzy (imar+1,jmar)); zxtzy (:,:)= 0.0
144  ALLOCATE(ztz   (imar+1,jmar)); ztz   (:,:)= 0.0
145  zmea(:,:)= 0.0
146  zpic(:,:)=-1.E+10
147  zval(:,:)= 1.E+10
148
149!--- COMPUTE SLOPES CORRELATIONS ON USN GRID
150! CORRELATIONS OF USN OROGRAPHY GRADIENTS  ! dim (imdp+2*iext,jmdp+2)
151  ALLOCATE(zytzyusn(imdp+2*iext,jmdp+2)); zytzyusn(:,:)=0.0
152  ALLOCATE(zxtzxusn(imdp+2*iext,jmdp+2)); zxtzxusn(:,:)=0.0
153  ALLOCATE(zxtzyusn(imdp+2*iext,jmdp+2)); zxtzyusn(:,:)=0.0
154  DO j = 2, jmdp+1
155    zdeltax=zdeltay*cos(yusn(j))
156    DO i = 2, imdp+2*iext-1
157      zytzyusn(i,j)=(zusn(i,j+1)-zusn(i,j-1))**2/zdeltay**2
158      zxtzxusn(i,j)=(zusn(i+1,j)-zusn(i-1,j))**2/zdeltax**2
159      zxtzyusn(i,j)=(zusn(i,j+1)-zusn(i,j-1))   /zdeltay  &
160     &             *(zusn(i+1,j)-zusn(i-1,j))   /zdeltax
161    END DO
162  END DO
163
164!--- SUMMATION OVER GRIDPOINT AREA
165  zleny=xpi/REAL(jmdp)*rad
166  xincr=xpi/REAL(jmdp)/2.
167  ALLOCATE(num_tot(imar+1,jmar)); num_tot(:,:)=0.
168  ALLOCATE(num_lan(imar+1,jmar)); num_lan(:,:)=0.
169  DO ii = 1, imar+1
170    DO jj = 1, jmar
171      DO j = 2,jmdp+1
172        zlenx  =zleny  *COS(yusn(j))
173        zdeltax=zdeltay*COS(yusn(j))
174        zbordnor=(xincr+c(jj)-yusn(j))*rad
175        zbordsud=(xincr-d(jj)+yusn(j))*rad
176        weighy=AMAX1(0.,AMIN1(zbordnor,zbordsud,zleny))
177        IF(weighy==0.) CYCLE
178        DO i = 2, imdp+2*iext-1
179          zbordest=(xusn(i)-a(ii)+xincr)*rad*COS(yusn(j))
180          zbordoue=(b(ii)+xincr-xusn(i))*rad*COS(yusn(j))
181          weighx=AMAX1(0.,AMIN1(zbordest,zbordoue,zlenx))
182          IF(weighx==0.) CYCLE
183          num_tot(ii,jj)=num_tot(ii,jj)+1.0
184          IF(zusn(i,j)>=1.)num_lan(ii,jj)=num_lan(ii,jj)+1.0
185          weight(ii,jj)=weight(ii,jj)+weighx*weighy
186          zxtzx(ii,jj)=zxtzx(ii,jj)+zxtzxusn(i,j)*weighx*weighy
187          zytzy(ii,jj)=zytzy(ii,jj)+zytzyusn(i,j)*weighx*weighy
188          zxtzy(ii,jj)=zxtzy(ii,jj)+zxtzyusn(i,j)*weighx*weighy
189          ztz  (ii,jj)=  ztz(ii,jj)+zusn(i,j)*zusn(i,j)*weighx*weighy
190          zmea (ii,jj)= zmea(ii,jj)+zusn(i,j)*weighx*weighy !--- MEAN
191          zpic (ii,jj)=AMAX1(zpic(ii,jj),zusn(i,j))         !--- PEAKS
192          zval (ii,jj)=AMIN1(zval(ii,jj),zusn(i,j))         !--- VALLEYS
193        END DO
194      END DO
195    END DO
196  END DO
197
198!--- COMPUTE PARAMETERS NEEDED BY LOTT & MILLER (1997) AND LOTT (1999) SSO SCHEME
199  IF(.NOT.masque_lu) THEN
200    WHERE(weight(:,1:jmar-1)/=0.0) mask=num_lan(:,:)/num_tot(:,:)
201  END IF
202  nn=COUNT(weight(:,1:jmar-1)==0.0)
203  IF(nn/=0) WRITE(lunout,*)'Problem with weight ; vanishing occurrences: ',nn
204  WHERE(weight(:,:)/=0.0)
205    zmea (:,:)=zmea (:,:)/weight(:,:)
206    zxtzx(:,:)=zxtzx(:,:)/weight(:,:)
207    zytzy(:,:)=zytzy(:,:)/weight(:,:)
208    zxtzy(:,:)=zxtzy(:,:)/weight(:,:)
209    ztz  (:,:)=ztz  (:,:)/weight(:,:)
210    zstd (:,:)=ztz  (:,:)-zmea(:,:)**2
211  END WHERE
212  WHERE(zstd(:,:)<0) zstd(:,:)=0.
213  zstd (:,:)=SQRT(zstd(:,:))
214
215!--- CORRECT VALUES OF HORIZONTAL SLOPE NEAR THE POLES:
216  zxtzx(:,   1)=zxtzx(:,     2)
217  zxtzx(:,jmar)=zxtzx(:,jmar-1)
218  zxtzy(:,   1)=zxtzy(:,     2)
219  zxtzy(:,jmar)=zxtzy(:,jmar-1)
220  zytzy(:,   1)=zytzy(:,     2)
221  zytzy(:,jmar)=zytzy(:,jmar-1)
222
223!=== FILTERS TO SMOOTH OUT FIELDS FOR INPUT INTO SSO SCHEME.
224!--- FIRST FILTER, MOVING AVERAGE OVER 9 POINTS.
225!-------------------------------------------------------------------------------
226  ALLOCATE(zmea0(imar+1,jmar))
227  zmea0(:,:)=zmea(:,:)                           ! GK211005 (CG) UNSMOOTHED TOPO
228  CALL MVA9(zmea);  CALL MVA9(zstd);  CALL MVA9(zpic);  CALL MVA9(zval)
229  CALL MVA9(zxtzx); CALL MVA9(zxtzy); CALL MVA9(zytzy)
230
231!--- MASK BASED ON GROUND MAXIMUM, 10% THRESHOLD. (SURFACE PARAMS MEANINGLESS)
232  ALLOCATE(mask_tmp(imar+1,jmar)); mask_tmp(:,:)=0.0
233  WHERE(mask>=0.1) mask_tmp = 1.
234  WHERE(weight(:,:)/=0.0)
235!   zphi (:,:)= mask_tmp(:,:)*zmea (:,:) ! GK211005 (CG) not necessarly smoothed
236    zphi (:,:)= mask_tmp(:,:)*zmea0(:,:)
237    zmea0(:,:)= mask_tmp(:,:)*zmea0(:,:)
238    zmea (:,:)= mask_tmp(:,:)*zmea (:,:)
239    zpic (:,:)= mask_tmp(:,:)*zpic (:,:)
240    zval (:,:)= mask_tmp(:,:)*zval (:,:)
241    zstd (:,:)= mask_tmp(:,:)*zstd (:,:)
242  END WHERE
243  DO ii = 1, imar
244    DO jj = 1, jmar
245      IF (weight(ii,jj)/=0.0) THEN
246      !--- Coefficients K, L et M:
247        xk=(zxtzx(ii,jj)+zytzy(ii,jj))/2.
248        xl=(zxtzx(ii,jj)-zytzy(ii,jj))/2.
249        xm=zxtzy(ii,jj)
250        xp=xk-SQRT(xl**2+xm**2)
251        xq=xk+SQRT(xl**2+xm**2)
252        xw=1.e-8
253        IF(xp<=xw) xp=0.
254        IF(xq<=xw) xq=xw
255        IF(ABS(xm)<=xw) xm=xw*SIGN(1.,xm)
256      !--- SLOPE
257        zsig(ii,jj)=SQRT(xq)*mask_tmp(ii,jj)
258      !---ISOTROPY
259        zgam(ii,jj)=xp/xq*mask_tmp(ii,jj)
260      !--- THETA ANGLE
261        zthe(ii,jj)=57.29577951*ATAN2(xm,xl)/2.*mask_tmp(ii,jj)
262      END IF
263    END DO
264  END DO
265  WRITE(lunout,*)'  MEAN ORO:' ,MAXVAL(zmea)
266  WRITE(lunout,*)'  ST. DEV.:' ,MAXVAL(zstd)
267  WRITE(lunout,*)'  PENTE:'    ,MAXVAL(zsig)
268  WRITE(lunout,*)'  ANISOTROP:',MAXVAL(zgam)
269  WRITE(lunout,*)'  ANGLE:'    ,MINVAL(zthe),MAXVAL(zthe)
270  WRITE(lunout,*)'  pic:'      ,MAXVAL(zpic)
271  WRITE(lunout,*)'  val:'      ,MAXVAL(zval)
272     
273!--- Values at poles
274  zmea0(imar+1,:)=zmea0(1,:)
275  zmea (imar+1,:)=zmea (1,:)
276  zphi (imar+1,:)=zphi (1,:)
277  zpic (imar+1,:)=zpic (1,:)
278  zval (imar+1,:)=zval (1,:)
279  zstd (imar+1,:)=zstd (1,:)
280  zsig (imar+1,:)=zsig (1,:)
281  zgam (imar+1,:)=zgam (1,:)
282  zthe (imar+1,:)=zthe (1,:)
283
284  zweinor =SUM(weight(1:imar,   1),DIM=1)
285  zweisud =SUM(weight(1:imar,jmar),DIM=1)
286  zmeanor0=SUM(weight(1:imar,   1)*zmea0(1:imar,   1),DIM=1)
287  zmeasud0=SUM(weight(1:imar,jmar)*zmea0(1:imar,jmar),DIM=1)
288  zmeanor =SUM(weight(1:imar,   1)*zmea (1:imar,   1),DIM=1)
289  zmeasud =SUM(weight(1:imar,jmar)*zmea (1:imar,jmar),DIM=1)
290  zstdnor =SUM(weight(1:imar,   1)*zstd (1:imar,   1),DIM=1)
291  zstdsud =SUM(weight(1:imar,jmar)*zstd (1:imar,jmar),DIM=1)
292  zsignor =SUM(weight(1:imar,   1)*zsig (1:imar,   1),DIM=1)
293  zsigsud =SUM(weight(1:imar,jmar)*zsig (1:imar,jmar),DIM=1)
294  zpicnor =SUM(weight(1:imar,   1)*zpic (1:imar,   1),DIM=1)
295  zpicsud =SUM(weight(1:imar,jmar)*zpic (1:imar,jmar),DIM=1)
296  zvalnor =SUM(weight(1:imar,   1)*zval (1:imar,   1),DIM=1)
297  zvalsud =SUM(weight(1:imar,jmar)*zval (1:imar,jmar),DIM=1)
298
299  zmea(:,1)=zmeanor /zweinor; zmea(:,jmar)=zmeasud /zweisud
300!  zphi(:,1)=zmeanor0/zweinor; zphi(:,jmar)=zmeasud0/zweisud   TO COMMIT
301  zphi(:,1)=zmeanor /zweinor; zphi(:,jmar)=zmeasud /zweisud
302  zpic(:,1)=zpicnor /zweinor; zpic(:,jmar)=zpicsud /zweisud
303  zval(:,1)=zvalnor /zweinor; zval(:,jmar)=zvalsud /zweisud
304  zstd(:,1)=zstdnor /zweinor; zstd(:,jmar)=zstdsud /zweisud
305  zsig(:,1)=zsignor /zweinor; zsig(:,jmar)=zsigsud /zweisud
306  zgam(:,1)=1.;               zgam(:,jmar)=1.
307  zthe(:,1)=0.;               zthe(:,jmar)=0.
308
309END SUBROUTINE grid_noro
310!
311!-------------------------------------------------------------------------------
312
313
314!-------------------------------------------------------------------------------
315!
316SUBROUTINE grid_noro0(xd,yd,zd,x,y,zphi,mask)
317!
318!===============================================================================
319! Purpose: Extracted from grid_noro to provide geopotential height for dynamics
320!          without any call to physics subroutines.
321!===============================================================================
322  IMPLICIT NONE
323!-------------------------------------------------------------------------------
324! Arguments:
325  REAL, INTENT(IN)   :: xd(:), yd(:) !--- INPUT  COORDINATES     (imdp) (jmdp)
326  REAL, INTENT(IN)   :: zd(:,:)      !--- INPUT  FIELD           (imdp,jmdp)
327  REAL, INTENT(IN)   :: x(:), y(:)   !--- OUTPUT COORDINATES     (imar+1) (jmar)
328  REAL, INTENT(OUT)  :: zphi(:,:)    !--- GEOPOTENTIAL           (imar+1,jmar)
329  REAL, INTENT(INOUT):: mask(:,:)    !--- MASK                   (imar+1,jmar)
330!-------------------------------------------------------------------------------
331! Local variables:
332  CHARACTER(LEN=256) :: modname="grid_noro0"
333  REAL, ALLOCATABLE :: xusn(:), yusn(:)           ! dim (imdp+2*iext) (jmdp+2)
334  REAL, ALLOCATABLE :: zusn(:,:)                  ! dim (imdp+2*iext,jmdp+2)
335  REAL, ALLOCATABLE :: weight(:,:)                ! dim (imar+1,jmar)
336  REAL, ALLOCATABLE :: mask_tmp(:,:), zmea(:,:)   ! dim (imar+1,jmar)
337  REAL, ALLOCATABLE :: num_tot(:,:), num_lan(:,:) ! dim (imax,jmax)
338  REAL, ALLOCATABLE :: a(:), b(:)                 ! dim (imax)
339  REAL, ALLOCATABLE :: c(:), d(:)                 ! dim (jmax)
340  LOGICAL :: masque_lu
341  INTEGER :: i, ii, imdp, imar, iext
342  INTEGER :: j, jj, jmdp, jmar, nn
343  REAL    :: xpi, zlenx, weighx, xincr,  zbordnor, zmeanor, zweinor, zbordest
344  REAL    :: rad, zleny, weighy, masque, zbordsud, zmeasud, zweisud, zbordoue
345!-------------------------------------------------------------------------------
346  imdp=assert_eq(SIZE(xd),SIZE(zd,1),TRIM(modname)//" imdp")
347  jmdp=assert_eq(SIZE(yd),SIZE(zd,2),TRIM(modname)//" jmdp")
348  imar=assert_eq(SIZE(x),SIZE(zphi,1),SIZE(mask,1),TRIM(modname)//" imar")-1
349  jmar=assert_eq(SIZE(y),SIZE(zphi,2),SIZE(mask,2),TRIM(modname)//" jmar")
350! IF(imar/=iim)   CALL abort_gcm(TRIM(modname),'imar/=iim'  ,1)
351! IF(jmar/=jjm+1) CALL abort_gcm(TRIM(modname),'jmar/=jjm+1',1)
352  iext=imdp/10
353  xpi = ACOS(-1.)
354  rad = 6371229.
355
356!--- ARE WE USING A READ MASK ?
357  masque_lu=ANY(mask/=-99999.); IF(.NOT.masque_lu) mask=0.0
358  WRITE(lunout,*)'Masque lu: ',masque_lu
359
360!--- EXTENSION OF THE INPUT DATABASE TO PROCEED COMPUTATIONS AT BOUNDARIES:
361  ALLOCATE(xusn(imdp+2*iext))
362  xusn(1     +iext:imdp  +iext)=xd(:)
363  xusn(1          :       iext)=xd(1+imdp-iext:imdp)-2.*xpi
364  xusn(1+imdp+iext:imdp+2*iext)=xd(1          :iext)+2.*xpi
365
366  ALLOCATE(yusn(jmdp+2))
367  yusn(1       )=yd(1)   +(yd(1)   -yd(2))
368  yusn(2:jmdp+1)=yd(:)
369  yusn(  jmdp+2)=yd(jmdp)+(yd(jmdp)-yd(jmdp-1))
370
371  ALLOCATE(zusn(imdp+2*iext,jmdp+2))
372  zusn(1       +iext:imdp  +iext,2:jmdp+1)=zd  (:                   ,     :)
373  zusn(1            :       iext,2:jmdp+1)=zd  (imdp-iext+1:imdp    ,     :)
374  zusn(1+imdp  +iext:imdp+2*iext,2:jmdp+1)=zd  (1:iext              ,     :)
375  zusn(1            :imdp/2+iext,       1)=zusn(1+imdp/2:imdp  +iext,     2)
376  zusn(1+imdp/2+iext:imdp+2*iext,       1)=zusn(1       :imdp/2+iext,     2)
377  zusn(1            :imdp/2+iext,  jmdp+2)=zusn(1+imdp/2:imdp  +iext,jmdp+1)
378  zusn(1+imdp/2+iext:imdp+2*iext,  jmdp+2)=zusn(1       :imdp/2+iext,jmdp+1)
379
380!--- COMPUTE LIMITS OF MODEL GRIDPOINT AREA (REGULAR GRID)
381  ALLOCATE(a(imar+1),b(imar+1))
382  b(1:imar)=(x(1:imar  )+ x(2:imar+1))/2.0
383  b(imar+1)= x(  imar+1)+(x(  imar+1)-x(imar))/2.0
384  a(1)=x(1)-(x(2)-x(1))/2.0
385  a(2:imar+1)= b(1:imar)
386
387  ALLOCATE(c(jmar),d(jmar))
388  d(1:jmar-1)=(y(1:jmar-1)+ y(2:jmar))/2.0
389  d(  jmar  )= y(  jmar  )+(y(  jmar)-y(jmar-1))/2.0
390  c(1)=y(1)-(y(2)-y(1))/2.0
391  c(2:jmar)=d(1:jmar-1)
392
393!--- INITIALIZATIONS:
394  ALLOCATE(weight(imar+1,jmar)); weight(:,:)= 0.0
395  ALLOCATE(zmea  (imar+1,jmar)); zmea  (:,:)= 0.0
396
397!--- SUMMATION OVER GRIDPOINT AREA
398  zleny=xpi/REAL(jmdp)*rad
399  xincr=xpi/REAL(jmdp)/2.
400  ALLOCATE(num_tot(imar+1,jmar)); num_tot(:,:)=0.
401  ALLOCATE(num_lan(imar+1,jmar)); num_lan(:,:)=0.
402  DO ii = 1, imar+1
403    DO jj = 1, jmar
404      DO j = 2,jmdp+1
405        zlenx  =zleny  *COS(yusn(j))
406        zbordnor=(xincr+c(jj)-yusn(j))*rad
407        zbordsud=(xincr-d(jj)+yusn(j))*rad
408        weighy=AMAX1(0.,AMIN1(zbordnor,zbordsud,zleny))
409        IF(weighy/=0) THEN
410          DO i = 2, imdp+2*iext-1
411            zbordest=(xusn(i)-a(ii)+xincr)*rad*COS(yusn(j))
412            zbordoue=(b(ii)+xincr-xusn(i))*rad*COS(yusn(j))
413            weighx=AMAX1(0.,AMIN1(zbordest,zbordoue,zlenx))
414            IF(weighx/=0)THEN
415              num_tot(ii,jj)=num_tot(ii,jj)+1.0
416              IF(zusn(i,j)>=1.)num_lan(ii,jj)=num_lan(ii,jj)+1.0
417              weight(ii,jj)=weight(ii,jj)+weighx*weighy
418              zmea  (ii,jj)=zmea  (ii,jj)+zusn(i,j)*weighx*weighy !--- MEAN
419            END IF
420          END DO
421        END IF
422      END DO
423    END DO
424  END DO
425
426!--- COMPUTE PARAMETERS NEEDED BY LOTT & MILLER (1997) AND LOTT (1999) SSO SCHEME
427  IF(.NOT.masque_lu) THEN
428    WHERE(weight(:,1:jmar-1)/=0.0) mask=num_lan(:,:)/num_tot(:,:)
429  END IF
430  nn=COUNT(weight(:,1:jmar-1)==0.0)
431  IF(nn/=0) WRITE(lunout,*)'Problem with weight ; vanishing occurrences: ',nn
432  WHERE(weight/=0.0) zmea(:,:)=zmea(:,:)/weight(:,:)
433
434!--- MASK BASED ON GROUND MAXIMUM, 10% THRESHOLD (<10%: SURF PARAMS MEANINGLESS)
435  ALLOCATE(mask_tmp(imar+1,jmar)); mask_tmp(:,:)=0.0
436  WHERE(mask>=0.1) mask_tmp = 1.
437  WHERE(weight(:,:)/=0.0)
438    zphi(:,:)=mask_tmp(:,:)*zmea(:,:)
439    zmea(:,:)=mask_tmp(:,:)*zmea(:,:)
440  END WHERE
441  WRITE(lunout,*)'  MEAN ORO:' ,MAXVAL(zmea)
442
443!--- Values at poles
444  zphi(imar+1,:)=zphi(1,:)
445
446  zweinor=SUM(weight(1:imar,   1),DIM=1)
447  zweisud=SUM(weight(1:imar,jmar),DIM=1)
448  zmeanor=SUM(weight(1:imar,   1)*zmea(1:imar,   1),DIM=1)
449  zmeasud=SUM(weight(1:imar,jmar)*zmea(1:imar,jmar),DIM=1)
450  zphi(:,1)=zmeanor/zweinor; zphi(:,jmar)=zmeasud/zweisud
451
452END SUBROUTINE grid_noro0
453!
454!-------------------------------------------------------------------------------
455
456
457!-------------------------------------------------------------------------------
458!
459SUBROUTINE MVA9(x)
460!
461!-------------------------------------------------------------------------------
462  IMPLICIT NONE
463! MAKE A MOVING AVERAGE OVER 9 GRIDPOINTS OF THE X FIELDS
464!-------------------------------------------------------------------------------
465! Arguments:
466  REAL, INTENT(INOUT) :: x(:,:)
467!-------------------------------------------------------------------------------
468! Local variables:
469  REAL    :: xf(SIZE(x,DIM=1),SIZE(x,DIM=2)), WEIGHTpb(-1:1,-1:1)
470  INTEGER :: i, j, imar, jmar
471!-------------------------------------------------------------------------------
472  WEIGHTpb=RESHAPE([((1./REAL((1+i**2)*(1+j**2)),i=-1,1),j=-1,1)],SHAPE=[3,3])
473  WEIGHTpb=WEIGHTpb/SUM(WEIGHTpb)
474  imar=SIZE(X,DIM=1); jmar=SIZE(X,DIM=2)
475  DO j=2,jmar-1
476    DO i=2,imar-1
477      xf(i,j)=SUM(x(i-1:i+1,j-1:j+1)*WEIGHTpb(:,:))
478    END DO
479  END DO
480  DO j=2,jmar-1
481    xf(1,j)=SUM(x(imar-1,j-1:j+1)*WEIGHTpb(-1,:))
482    xf(1,j)=xf(1,j)+SUM(x(1:2,j-1:j+1)*WEIGHTpb(0:1,-1:1))
483    xf(imar,j)=xf(1,j)
484  END DO
485  xf(:,   1)=xf(:,     2)
486  xf(:,jmar)=xf(:,jmar-1)
487  x(:,:)=xf(:,:)
488
489END SUBROUTINE MVA9
490!
491!-------------------------------------------------------------------------------
492
493
494END MODULE grid_noro_m
495
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