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source: palm/trunk/SOURCE/init_grid.f90 @ 183

Last change on this file since 183 was 145, checked in by raasch, 17 years ago
second preliminary update for turbulent inflow
Property svn:keywords set to `Id`
File size: 36.3 KB

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1	SUBROUTINE init_grid
2
3	!------------------------------------------------------------------------------!
4	! Actual revisions:
5	! -----------------
6	!
7	!
8	! Former revisions:
9	! -----------------
10	! $Id: init_grid.f90 145 2008-01-09 08:17:38Z letzel $
11	!
12	! 134 2007-11-21 07:28:38Z letzel
13	! Redefine initial nzb_local as the actual total size of topography (later the
14	! extent of topography in nzb_local is reduced by 1dx at the E topography walls
15	! and by 1dy at the N topography walls to form the basis for nzb_s_inner);
16	! for consistency redefine 'single_building' case.
17	! Calculation of wall flag arrays
18	!
19	! 94 2007-06-01 15:25:22Z raasch
20	! Grid definition for ocean version
21	!
22	! 75 2007-03-22 09:54:05Z raasch
23	! storage of topography height arrays zu_s_inner and zw_s_inner,
24	! 2nd+3rd argument removed from exchange horiz
25	!
26	! 19 2007-02-23 04:53:48Z raasch
27	! Setting of nzt_diff
28	!
29	! RCS Log replace by Id keyword, revision history cleaned up
30	!
31	! Revision 1.17 2006/08/22 14:00:05 raasch
32	! +dz_max to limit vertical stretching,
33	! bugfix in index array initialization for line- or point-like topography
34	! structures
35	!
36	! Revision 1.1 1997/08/11 06:17:45 raasch
37	! Initial revision (Testversion)
38	!
39	!
40	! Description:
41	! ------------
42	! Creating grid depending constants
43	!------------------------------------------------------------------------------!
44
45	USE arrays_3d
46	USE control_parameters
47	USE grid_variables
48	USE indices
49	USE pegrid
50
51	IMPLICIT NONE
52
53	INTEGER :: bh, blx, bly, bxl, bxr, byn, bys, gls, i, inc, i_center, j, &
54	j_center, k, l, nxl_l, nxr_l, nyn_l, nys_l, nzb_si, nzt_l, vi
55
56	INTEGER, DIMENSION(:), ALLOCATABLE :: vertical_influence
57
58	INTEGER, DIMENSION(:,:), ALLOCATABLE :: corner_nl, corner_nr, corner_sl, &
59	corner_sr, wall_l, wall_n, wall_r,&
60	wall_s, nzb_local, nzb_tmp
61
62	REAL :: dx_l, dy_l, dz_stretched
63
64	REAL, DIMENSION(0:ny,0:nx) :: topo_height
65
66	REAL, DIMENSION(:,:,:), ALLOCATABLE :: distance
67
68	!
69	!-- Allocate grid arrays
70	ALLOCATE( ddzu(1:nzt+1), ddzw(1:nzt+1), dd2zu(1:nzt), dzu(1:nzt+1), &
71	dzw(1:nzt+1), l_grid(1:nzt), zu(0:nzt+1), zw(0:nzt+1) )
72
73	!
74	!-- Compute height of u-levels from constant grid length and dz stretch factors
75	IF ( dz == -1.0 ) THEN
76	IF ( myid == 0 ) PRINT*,'+++ init_grid: missing dz'
77	CALL local_stop
78	ELSEIF ( dz <= 0.0 ) THEN
79	IF ( myid == 0 ) PRINT*,'+++ init_grid: dz=',dz,' <= 0.0'
80	CALL local_stop
81	ENDIF
82
83	!
84	!-- Define the vertical grid levels
85	IF ( .NOT. ocean ) THEN
86	!
87	!-- Grid for atmosphere with surface at z=0 (k=0, w-grid).
88	!-- Since the w-level lies on the surface, the first u-level (staggered!)
89	!-- lies below the surface (used for "mirror" boundary condition).
90	!-- The first u-level above the surface corresponds to the top of the
91	!-- Prandtl-layer.
92	zu(0) = - dz * 0.5
93	zu(1) = dz * 0.5
94
95	dz_stretch_level_index = nzt+1
96	dz_stretched = dz
97	DO k = 2, nzt+1
98	IF ( dz_stretch_level <= zu(k-1) .AND. dz_stretched < dz_max ) THEN
99	dz_stretched = dz_stretched * dz_stretch_factor
100	dz_stretched = MIN( dz_stretched, dz_max )
101	IF ( dz_stretch_level_index == nzt+1 ) dz_stretch_level_index = k-1
102	ENDIF
103	zu(k) = zu(k-1) + dz_stretched
104	ENDDO
105
106	!
107	!-- Compute the w-levels. They are always staggered half-way between the
108	!-- corresponding u-levels. The top w-level is extrapolated linearly.
109	zw(0) = 0.0
110	DO k = 1, nzt
111	zw(k) = ( zu(k) + zu(k+1) ) * 0.5
112	ENDDO
113	zw(nzt+1) = zw(nzt) + 2.0 * ( zu(nzt+1) - zw(nzt) )
114
115	ELSE
116	!
117	!-- Grid for ocean with solid surface at z=0 (k=0, w-grid). The free water
118	!-- surface is at k=nzt (w-grid).
119	!-- Since the w-level lies always on the surface, the first/last u-level
120	!-- (staggered!) lies below the bottom surface / above the free surface.
121	!-- It is used for "mirror" boundary condition.
122	!-- The first u-level above the bottom surface corresponds to the top of the
123	!-- Prandtl-layer.
124	zu(nzt+1) = dz * 0.5
125	zu(nzt) = - dz * 0.5
126
127	dz_stretch_level_index = 0
128	dz_stretched = dz
129	DO k = nzt-1, 0, -1
130	IF ( dz_stretch_level <= ABS( zu(k+1) ) .AND. &
131	dz_stretched < dz_max ) THEN
132	dz_stretched = dz_stretched * dz_stretch_factor
133	dz_stretched = MIN( dz_stretched, dz_max )
134	IF ( dz_stretch_level_index == 0 ) dz_stretch_level_index = k+1
135	ENDIF
136	zu(k) = zu(k+1) - dz_stretched
137	ENDDO
138
139	!
140	!-- Compute the w-levels. They are always staggered half-way between the
141	!-- corresponding u-levels.
142	!-- The top w-level (nzt+1) is not used but set for consistency, since
143	!-- w and all scalar variables are defined up tp nzt+1.
144	zw(nzt+1) = dz
145	zw(nzt) = 0.0
146	DO k = 0, nzt
147	zw(k) = ( zu(k) + zu(k+1) ) * 0.5
148	ENDDO
149
150	ENDIF
151
152	!
153	!-- Compute grid lengths.
154	DO k = 1, nzt+1
155	dzu(k) = zu(k) - zu(k-1)
156	ddzu(k) = 1.0 / dzu(k)
157	dzw(k) = zw(k) - zw(k-1)
158	ddzw(k) = 1.0 / dzw(k)
159	ENDDO
160
161	DO k = 1, nzt
162	dd2zu(k) = 1.0 / ( dzu(k) + dzu(k+1) )
163	ENDDO
164
165	!
166	!-- In case of multigrid method, compute grid lengths and grid factors for the
167	!-- grid levels
168	IF ( psolver == 'multigrid' ) THEN
169
170	ALLOCATE( ddx2_mg(maximum_grid_level), ddy2_mg(maximum_grid_level), &
171	dzu_mg(nzb+1:nzt+1,maximum_grid_level), &
172	dzw_mg(nzb+1:nzt+1,maximum_grid_level), &
173	f1_mg(nzb+1:nzt,maximum_grid_level), &
174	f2_mg(nzb+1:nzt,maximum_grid_level), &
175	f3_mg(nzb+1:nzt,maximum_grid_level) )
176
177	dzu_mg(:,maximum_grid_level) = dzu
178	dzw_mg(:,maximum_grid_level) = dzw
179	nzt_l = nzt
180	DO l = maximum_grid_level-1, 1, -1
181	dzu_mg(nzb+1,l) = 2.0 * dzu_mg(nzb+1,l+1)
182	dzw_mg(nzb+1,l) = 2.0 * dzw_mg(nzb+1,l+1)
183	nzt_l = nzt_l / 2
184	DO k = 2, nzt_l+1
185	dzu_mg(k,l) = dzu_mg(2k-2,l+1) + dzu_mg(2k-1,l+1)
186	dzw_mg(k,l) = dzw_mg(2k-2,l+1) + dzw_mg(2k-1,l+1)
187	ENDDO
188	ENDDO
189
190	nzt_l = nzt
191	dx_l = dx
192	dy_l = dy
193	DO l = maximum_grid_level, 1, -1
194	ddx2_mg(l) = 1.0 / dx_l**2
195	ddy2_mg(l) = 1.0 / dy_l**2
196	DO k = nzb+1, nzt_l
197	f2_mg(k,l) = 1.0 / ( dzu_mg(k+1,l) * dzw_mg(k,l) )
198	f3_mg(k,l) = 1.0 / ( dzu_mg(k,l) * dzw_mg(k,l) )
199	f1_mg(k,l) = 2.0 * ( ddx2_mg(l) + ddy2_mg(l) ) + &
200	f2_mg(k,l) + f3_mg(k,l)
201	ENDDO
202	nzt_l = nzt_l / 2
203	dx_l = dx_l * 2.0
204	dy_l = dy_l * 2.0
205	ENDDO
206
207	ENDIF
208
209	!
210	!-- Compute the reciprocal values of the horizontal grid lengths.
211	ddx = 1.0 / dx
212	ddy = 1.0 / dy
213	dx2 = dx * dx
214	dy2 = dy * dy
215	ddx2 = 1.0 / dx2
216	ddy2 = 1.0 / dy2
217
218	!
219	!-- Compute the grid-dependent mixing length.
220	DO k = 1, nzt
221	l_grid(k) = ( dx * dy * dzw(k) )**0.33333333333333
222	ENDDO
223
224	!
225	!-- Allocate outer and inner index arrays for topography and set
226	!-- defaults.
227	!-- nzb_local has to contain additional layers of ghost points for calculating
228	!-- the flag arrays needed for the multigrid method
229	gls = 2**( maximum_grid_level )
230	ALLOCATE( corner_nl(nys:nyn,nxl:nxr), corner_nr(nys:nyn,nxl:nxr), &
231	corner_sl(nys:nyn,nxl:nxr), corner_sr(nys:nyn,nxl:nxr), &
232	nzb_local(-gls:ny+gls,-gls:nx+gls), nzb_tmp(-1:ny+1,-1:nx+1), &
233	wall_l(nys:nyn,nxl:nxr), wall_n(nys:nyn,nxl:nxr), &
234	wall_r(nys:nyn,nxl:nxr), wall_s(nys:nyn,nxl:nxr) )
235	ALLOCATE( fwxm(nys-1:nyn+1,nxl-1:nxr+1), fwxp(nys-1:nyn+1,nxl-1:nxr+1), &
236	fwym(nys-1:nyn+1,nxl-1:nxr+1), fwyp(nys-1:nyn+1,nxl-1:nxr+1), &
237	fxm(nys-1:nyn+1,nxl-1:nxr+1), fxp(nys-1:nyn+1,nxl-1:nxr+1), &
238	fym(nys-1:nyn+1,nxl-1:nxr+1), fyp(nys-1:nyn+1,nxl-1:nxr+1), &
239	nzb_s_inner(nys-1:nyn+1,nxl-1:nxr+1), &
240	nzb_s_outer(nys-1:nyn+1,nxl-1:nxr+1), &
241	nzb_u_inner(nys-1:nyn+1,nxl-1:nxr+1), &
242	nzb_u_outer(nys-1:nyn+1,nxl-1:nxr+1), &
243	nzb_v_inner(nys-1:nyn+1,nxl-1:nxr+1), &
244	nzb_v_outer(nys-1:nyn+1,nxl-1:nxr+1), &
245	nzb_w_inner(nys-1:nyn+1,nxl-1:nxr+1), &
246	nzb_w_outer(nys-1:nyn+1,nxl-1:nxr+1), &
247	nzb_diff_s_inner(nys-1:nyn+1,nxl-1:nxr+1), &
248	nzb_diff_s_outer(nys-1:nyn+1,nxl-1:nxr+1), &
249	nzb_diff_u(nys-1:nyn+1,nxl-1:nxr+1), &
250	nzb_diff_v(nys-1:nyn+1,nxl-1:nxr+1), &
251	nzb_2d(nys-1:nyn+1,nxl-1:nxr+1), &
252	wall_e_x(nys-1:nyn+1,nxl-1:nxr+1), &
253	wall_e_y(nys-1:nyn+1,nxl-1:nxr+1), &
254	wall_u(nys-1:nyn+1,nxl-1:nxr+1), &
255	wall_v(nys-1:nyn+1,nxl-1:nxr+1), &
256	wall_w_x(nys-1:nyn+1,nxl-1:nxr+1), &
257	wall_w_y(nys-1:nyn+1,nxl-1:nxr+1) )
258
259	ALLOCATE( l_wall(nzb:nzt+1,nys-1:nyn+1,nxl-1:nxr+1) )
260
261	nzb_s_inner = nzb; nzb_s_outer = nzb
262	nzb_u_inner = nzb; nzb_u_outer = nzb
263	nzb_v_inner = nzb; nzb_v_outer = nzb
264	nzb_w_inner = nzb; nzb_w_outer = nzb
265
266	!
267	!-- Define vertical gridpoint from (or to) which on the usual finite difference
268	!-- form (which does not use surface fluxes) is applied
269	IF ( prandtl_layer .OR. use_surface_fluxes ) THEN
270	nzb_diff = nzb + 2
271	ELSE
272	nzb_diff = nzb + 1
273	ENDIF
274	IF ( use_top_fluxes ) THEN
275	nzt_diff = nzt - 1
276	ELSE
277	nzt_diff = nzt
278	ENDIF
279
280	nzb_diff_s_inner = nzb_diff; nzb_diff_s_outer = nzb_diff
281	nzb_diff_u = nzb_diff; nzb_diff_v = nzb_diff
282
283	wall_e_x = 0.0; wall_e_y = 0.0; wall_u = 0.0; wall_v = 0.0
284	wall_w_x = 0.0; wall_w_y = 0.0
285	fwxp = 1.0; fwxm = 1.0; fwyp = 1.0; fwym = 1.0
286	fxp = 1.0; fxm = 1.0; fyp = 1.0; fym = 1.0
287
288	!
289	!-- Initialize near-wall mixing length l_wall only in the vertical direction
290	!-- for the moment,
291	!-- multiplication with wall_adjustment_factor near the end of this routine
292	l_wall(nzb,:,:) = l_grid(1)
293	DO k = nzb+1, nzt
294	l_wall(k,:,:) = l_grid(k)
295	ENDDO
296	l_wall(nzt+1,:,:) = l_grid(nzt)
297
298	ALLOCATE ( vertical_influence(nzb:nzt) )
299	DO k = 1, nzt
300	vertical_influence(k) = MIN ( INT( l_grid(k) / &
301	( wall_adjustment_factor * dzw(k) ) + 0.5 ), nzt - k )
302	ENDDO
303
304	DO k = 1, MAXVAL( nzb_s_inner )
305	IF ( l_grid(k) > 1.5 * dx * wall_adjustment_factor .OR. &
306	l_grid(k) > 1.5 * dy * wall_adjustment_factor ) THEN
307	IF ( myid == 0 ) THEN
308	PRINT*, '+++ WARNING: grid anisotropy exceeds '// &
309	'threshold given by only local'
310	PRINT*, ' horizontal reduction of near_wall '// &
311	'mixing length l_wall'
312	PRINT*, ' starting from height level k = ', k, '.'
313	ENDIF
314	EXIT
315	ENDIF
316	ENDDO
317	vertical_influence(0) = vertical_influence(1)
318
319	DO i = nxl-1, nxr+1
320	DO j = nys-1, nyn+1
321	DO k = nzb_s_inner(j,i) + 1, &
322	nzb_s_inner(j,i) + vertical_influence(nzb_s_inner(j,i))
323	l_wall(k,j,i) = zu(k) - zw(nzb_s_inner(j,i))
324	ENDDO
325	ENDDO
326	ENDDO
327
328	!
329	!-- Set outer and inner index arrays for non-flat topography.
330	!-- Here consistency checks concerning domain size and periodicity are
331	!-- necessary.
332	!-- Within this SELECT CASE structure only nzb_local is initialized
333	!-- individually depending on the chosen topography type, all other index
334	!-- arrays are initialized further below.
335	SELECT CASE ( TRIM( topography ) )
336
337	CASE ( 'flat' )
338	!
339	!-- No actions necessary
340
341	CASE ( 'single_building' )
342	!
343	!-- Single rectangular building, by default centered in the middle of the
344	!-- total domain
345	blx = NINT( building_length_x / dx )
346	bly = NINT( building_length_y / dy )
347	bh = NINT( building_height / dz )
348
349	IF ( building_wall_left == 9999999.9 ) THEN
350	building_wall_left = ( nx + 1 - blx ) / 2 * dx
351	ENDIF
352	bxl = NINT( building_wall_left / dx )
353	bxr = bxl + blx
354
355	IF ( building_wall_south == 9999999.9 ) THEN
356	building_wall_south = ( ny + 1 - bly ) / 2 * dy
357	ENDIF
358	bys = NINT( building_wall_south / dy )
359	byn = bys + bly
360
361	!
362	!-- Building size has to meet some requirements
363	IF ( ( bxl < 1 ) .OR. ( bxr > nx-1 ) .OR. ( bxr < bxl+3 ) .OR. &
364	( bys < 1 ) .OR. ( byn > ny-1 ) .OR. ( byn < bys+3 ) ) THEN
365	IF ( myid == 0 ) THEN
366	PRINT*, '+++ init_grid: inconsistent building parameters:'
367	PRINT*, ' bxl=', bxl, 'bxr=', bxr, 'bys=', bys, &
368	'byn=', byn, 'nx=', nx, 'ny=', ny
369	ENDIF
370	CALL local_stop
371	ENDIF
372
373	!
374	!-- Set the actual total size of the building. Due to the staggered grid,
375	!-- the building will be displaced by -0.5dx in x-direction and by -0.5dy
376	!-- in y-direction compared to the scalar grid.
377	nzb_local = 0
378	nzb_local(bys:byn,bxl:bxr) = bh
379
380	CASE ( 'read_from_file' )
381	!
382	!-- Arbitrary irregular topography data in PALM format (exactly matching
383	!-- the grid size and total domain size)
384	OPEN( 90, FILE='TOPOGRAPHY_DATA', STATUS='OLD', FORM='FORMATTED', &
385	ERR=10 )
386	DO j = ny, 0, -1
387	READ( 90, *, ERR=11, END=11 ) ( topo_height(j,i), i = 0, nx )
388	ENDDO
389	!
390	!-- Calculate the index height of the topography
391	DO i = 0, nx
392	DO j = 0, ny
393	nzb_local(j,i) = NINT( topo_height(j,i) / dz )
394	ENDDO
395	ENDDO
396	!
397	!-- Add cyclic boundaries (additional layers are for calculating flag
398	!-- arrays needed for the multigrid sover)
399	nzb_local(-gls:-1,0:nx) = nzb_local(ny-gls+1:ny,0:nx)
400	nzb_local(ny+1:ny+gls,0:nx) = nzb_local(0:gls-1,0:nx)
401	nzb_local(:,-gls:-1) = nzb_local(:,nx-gls+1:nx)
402	nzb_local(:,nx+1:nx+gls) = nzb_local(:,0:gls-1)
403
404	GOTO 12
405
406	10 IF ( myid == 0 ) THEN
407	PRINT*, '+++ init_grid: file TOPOGRAPHY_DATA does not exist'
408	ENDIF
409	CALL local_stop
410
411	11 IF ( myid == 0 ) THEN
412	PRINT*, '+++ init_grid: errors in file TOPOGRAPHY_DATA'
413	ENDIF
414	CALL local_stop
415
416	12 CLOSE( 90 )
417
418	CASE DEFAULT
419	!
420	!-- The DEFAULT case is reached either if the parameter topography
421	!-- contains a wrong character string or if the user has coded a special
422	!-- case in the user interface. There, the subroutine user_init_grid
423	!-- checks which of these two conditions applies.
424	CALL user_init_grid( gls, nzb_local )
425
426	END SELECT
427
428	!
429	!-- Test output of nzb_local -1:ny+1,-1:nx+1
430	! WRITE (9,) ' nzb_local *'
431	! DO j = ny+1, -1, -1
432	! WRITE (9,'(194(1X,I2))') ( nzb_local(j,i), i = -1, nx+1 )
433	! ENDDO
434
435	!
436	!-- Consistency checks and index array initialization are only required for
437	!-- non-flat topography, also the initialization of topography heigth arrays
438	!-- zu_s_inner and zw_w_inner
439	IF ( TRIM( topography ) /= 'flat' ) THEN
440
441	!
442	!-- Consistency checks
443	IF ( MINVAL( nzb_local ) < 0 .OR. MAXVAL( nzb_local ) > nz + 1 ) THEN
444	IF ( myid == 0 ) THEN
445	PRINT*, '+++ init_grid: nzb_local values are outside the', &
446	'model domain'
447	PRINT*, ' MINVAL( nzb_local ) = ', MINVAL(nzb_local)
448	PRINT*, ' MAXVAL( nzb_local ) = ', MAXVAL(nzb_local)
449	ENDIF
450	CALL local_stop
451	ENDIF
452
453	IF ( bc_lr == 'cyclic' ) THEN
454	IF ( ANY( nzb_local(:,-1) /= nzb_local(:,nx) ) .OR. &
455	ANY( nzb_local(:,0) /= nzb_local(:,nx+1) ) ) THEN
456	IF ( myid == 0 ) THEN
457	PRINT*, '+++ init_grid: nzb_local does not fulfill cyclic', &
458	' boundary condition in x-direction'
459	ENDIF
460	CALL local_stop
461	ENDIF
462	ENDIF
463	IF ( bc_ns == 'cyclic' ) THEN
464	IF ( ANY( nzb_local(-1,:) /= nzb_local(ny,:) ) .OR. &
465	ANY( nzb_local(0,:) /= nzb_local(ny+1,:) ) ) THEN
466	IF ( myid == 0 ) THEN
467	PRINT*, '+++ init_grid: nzb_local does not fulfill cyclic', &
468	' boundary condition in y-direction'
469	ENDIF
470	CALL local_stop
471	ENDIF
472	ENDIF
473
474	!
475	!-- The array nzb_local as defined above describes the actual total size of
476	!-- topography which is defined by u=0 on the topography walls in x-direction
477	!-- and by v=0 on the topography walls in y-direction. However, PALM uses
478	!-- individual arrays nzb_u\|v\|w\|s_inner\|outer that are based on nzb_s_inner.
479	!-- Therefore, the extent of topography in nzb_local is now reduced by 1dx
480	!-- at the E topography walls and by 1dy at the N topography walls to form
481	!-- the basis for nzb_s_inner.
482	DO j = -gls, ny + gls
483	DO i = -gls, nx
484	nzb_local(j,i) = MIN( nzb_local(j,i), nzb_local(j,i+1) )
485	ENDDO
486	ENDDO
487	!-- apply cyclic boundary conditions in x-direction
488	nzb_local(:,nx+1:nx+gls) = nzb_local(:,0:gls-1)
489	DO i = -gls, nx + gls
490	DO j = -gls, ny
491	nzb_local(j,i) = MIN( nzb_local(j,i), nzb_local(j+1,i) )
492	ENDDO
493	ENDDO
494	!-- apply cyclic boundary conditions in y-direction
495	nzb_local(ny+1:ny+gls,:) = nzb_local(0:gls-1,:)
496
497	!
498	!-- Initialize index arrays nzb_s_inner and nzb_w_inner
499	nzb_s_inner = nzb_local(nys-1:nyn+1,nxl-1:nxr+1)
500	nzb_w_inner = nzb_local(nys-1:nyn+1,nxl-1:nxr+1)
501
502	!
503	!-- Initialize remaining index arrays:
504	!-- first pre-initialize them with nzb_s_inner...
505	nzb_u_inner = nzb_s_inner
506	nzb_u_outer = nzb_s_inner
507	nzb_v_inner = nzb_s_inner
508	nzb_v_outer = nzb_s_inner
509	nzb_w_outer = nzb_s_inner
510	nzb_s_outer = nzb_s_inner
511
512	!
513	!-- ...then extend pre-initialized arrays in their according directions
514	!-- based on nzb_local using nzb_tmp as a temporary global index array
515
516	!
517	!-- nzb_s_outer:
518	!-- extend nzb_local east-/westwards first, then north-/southwards
519	nzb_tmp = nzb_local(-1:ny+1,-1:nx+1)
520	DO j = -1, ny + 1
521	DO i = 0, nx
522	nzb_tmp(j,i) = MAX( nzb_local(j,i-1), nzb_local(j,i), &
523	nzb_local(j,i+1) )
524	ENDDO
525	ENDDO
526	DO i = nxl, nxr
527	DO j = nys, nyn
528	nzb_s_outer(j,i) = MAX( nzb_tmp(j-1,i), nzb_tmp(j,i), &
529	nzb_tmp(j+1,i) )
530	ENDDO
531	!
532	!-- non-cyclic boundary conditions (overwritten by call of
533	!-- exchange_horiz_2d_int below in case of cyclic boundary conditions)
534	IF ( nys == 0 ) THEN
535	j = -1
536	nzb_s_outer(j,i) = MAX( nzb_tmp(j+1,i), nzb_tmp(j,i) )
537	ENDIF
538	IF ( nys == ny ) THEN
539	j = ny + 1
540	nzb_s_outer(j,i) = MAX( nzb_tmp(j-1,i), nzb_tmp(j,i) )
541	ENDIF
542	ENDDO
543	!
544	!-- nzb_w_outer:
545	!-- identical to nzb_s_outer
546	nzb_w_outer = nzb_s_outer
547
548	!
549	!-- nzb_u_inner:
550	!-- extend nzb_local rightwards only
551	nzb_tmp = nzb_local(-1:ny+1,-1:nx+1)
552	DO j = -1, ny + 1
553	DO i = 0, nx + 1
554	nzb_tmp(j,i) = MAX( nzb_local(j,i-1), nzb_local(j,i) )
555	ENDDO
556	ENDDO
557	nzb_u_inner = nzb_tmp(nys-1:nyn+1,nxl-1:nxr+1)
558
559	!
560	!-- nzb_u_outer:
561	!-- extend current nzb_tmp (nzb_u_inner) north-/southwards
562	DO i = nxl, nxr
563	DO j = nys, nyn
564	nzb_u_outer(j,i) = MAX( nzb_tmp(j-1,i), nzb_tmp(j,i), &
565	nzb_tmp(j+1,i) )
566	ENDDO
567	!
568	!-- non-cyclic boundary conditions (overwritten by call of
569	!-- exchange_horiz_2d_int below in case of cyclic boundary conditions)
570	IF ( nys == 0 ) THEN
571	j = -1
572	nzb_u_outer(j,i) = MAX( nzb_tmp(j+1,i), nzb_tmp(j,i) )
573	ENDIF
574	IF ( nys == ny ) THEN
575	j = ny + 1
576	nzb_u_outer(j,i) = MAX( nzb_tmp(j-1,i), nzb_tmp(j,i) )
577	ENDIF
578	ENDDO
579
580	!
581	!-- nzb_v_inner:
582	!-- extend nzb_local northwards only
583	nzb_tmp = nzb_local(-1:ny+1,-1:nx+1)
584	DO i = -1, nx + 1
585	DO j = 0, ny + 1
586	nzb_tmp(j,i) = MAX( nzb_local(j-1,i), nzb_local(j,i) )
587	ENDDO
588	ENDDO
589	nzb_v_inner = nzb_tmp(nys-1:nyn+1,nxl-1:nxr+1)
590
591	!
592	!-- nzb_v_outer:
593	!-- extend current nzb_tmp (nzb_v_inner) right-/leftwards
594	DO j = nys, nyn
595	DO i = nxl, nxr
596	nzb_v_outer(j,i) = MAX( nzb_tmp(j,i-1), nzb_tmp(j,i), &
597	nzb_tmp(j,i+1) )
598	ENDDO
599	!
600	!-- non-cyclic boundary conditions (overwritten by call of
601	!-- exchange_horiz_2d_int below in case of cyclic boundary conditions)
602	IF ( nxl == 0 ) THEN
603	i = -1
604	nzb_v_outer(j,i) = MAX( nzb_tmp(j,i+1), nzb_tmp(j,i) )
605	ENDIF
606	IF ( nxr == nx ) THEN
607	i = nx + 1
608	nzb_v_outer(j,i) = MAX( nzb_tmp(j,i-1), nzb_tmp(j,i) )
609	ENDIF
610	ENDDO
611
612	!
613	!-- Exchange of lateral boundary values (parallel computers) and cyclic
614	!-- boundary conditions, if applicable.
615	!-- Since nzb_s_inner and nzb_w_inner are derived directly from nzb_local
616	!-- they do not require exchange and are not included here.
617	CALL exchange_horiz_2d_int( nzb_u_inner )
618	CALL exchange_horiz_2d_int( nzb_u_outer )
619	CALL exchange_horiz_2d_int( nzb_v_inner )
620	CALL exchange_horiz_2d_int( nzb_v_outer )
621	CALL exchange_horiz_2d_int( nzb_w_outer )
622	CALL exchange_horiz_2d_int( nzb_s_outer )
623
624	!
625	!-- Allocate and set the arrays containing the topography height
626	IF ( myid == 0 ) THEN
627
628	ALLOCATE( zu_s_inner(0:nx+1,0:ny+1), zw_w_inner(0:nx+1,0:ny+1) )
629
630	DO i = 0, nx + 1
631	DO j = 0, ny + 1
632	zu_s_inner(i,j) = zu(nzb_local(j,i))
633	zw_w_inner(i,j) = zw(nzb_local(j,i))
634	ENDDO
635	ENDDO
636
637	ENDIF
638
639	ENDIF
640
641	!
642	!-- Preliminary: to be removed after completion of the topography code!
643	!-- Set the former default k index arrays nzb_2d
644	nzb_2d = nzb
645
646	!
647	!-- Set the individual index arrays which define the k index from which on
648	!-- the usual finite difference form (which does not use surface fluxes) is
649	!-- applied
650	IF ( prandtl_layer .OR. use_surface_fluxes ) THEN
651	nzb_diff_u = nzb_u_inner + 2
652	nzb_diff_v = nzb_v_inner + 2
653	nzb_diff_s_inner = nzb_s_inner + 2
654	nzb_diff_s_outer = nzb_s_outer + 2
655	ELSE
656	nzb_diff_u = nzb_u_inner + 1
657	nzb_diff_v = nzb_v_inner + 1
658	nzb_diff_s_inner = nzb_s_inner + 1
659	nzb_diff_s_outer = nzb_s_outer + 1
660	ENDIF
661
662	!
663	!-- Calculation of wall switches and factors required by diffusion_u/v.f90 and
664	!-- for limitation of near-wall mixing length l_wall further below
665	corner_nl = 0
666	corner_nr = 0
667	corner_sl = 0
668	corner_sr = 0
669	wall_l = 0
670	wall_n = 0
671	wall_r = 0
672	wall_s = 0
673
674	DO i = nxl, nxr
675	DO j = nys, nyn
676	!
677	!-- u-component
678	IF ( nzb_u_outer(j,i) > nzb_u_outer(j+1,i) ) THEN
679	wall_u(j,i) = 1.0 ! north wall (location of adjacent fluid)
680	fym(j,i) = 0.0
681	fyp(j,i) = 1.0
682	ELSEIF ( nzb_u_outer(j,i) > nzb_u_outer(j-1,i) ) THEN
683	wall_u(j,i) = 1.0 ! south wall (location of adjacent fluid)
684	fym(j,i) = 1.0
685	fyp(j,i) = 0.0
686	ENDIF
687	!
688	!-- v-component
689	IF ( nzb_v_outer(j,i) > nzb_v_outer(j,i+1) ) THEN
690	wall_v(j,i) = 1.0 ! rigth wall (location of adjacent fluid)
691	fxm(j,i) = 0.0
692	fxp(j,i) = 1.0
693	ELSEIF ( nzb_v_outer(j,i) > nzb_v_outer(j,i-1) ) THEN
694	wall_v(j,i) = 1.0 ! left wall (location of adjacent fluid)
695	fxm(j,i) = 1.0
696	fxp(j,i) = 0.0
697	ENDIF
698	!
699	!-- w-component, also used for scalars, separate arrays for shear
700	!-- production of tke
701	IF ( nzb_w_outer(j,i) > nzb_w_outer(j+1,i) ) THEN
702	wall_e_y(j,i) = 1.0 ! north wall (location of adjacent fluid)
703	wall_w_y(j,i) = 1.0
704	fwym(j,i) = 0.0
705	fwyp(j,i) = 1.0
706	ELSEIF ( nzb_w_outer(j,i) > nzb_w_outer(j-1,i) ) THEN
707	wall_e_y(j,i) = -1.0 ! south wall (location of adjacent fluid)
708	wall_w_y(j,i) = 1.0
709	fwym(j,i) = 1.0
710	fwyp(j,i) = 0.0
711	ENDIF
712	IF ( nzb_w_outer(j,i) > nzb_w_outer(j,i+1) ) THEN
713	wall_e_x(j,i) = 1.0 ! right wall (location of adjacent fluid)
714	wall_w_x(j,i) = 1.0
715	fwxm(j,i) = 0.0
716	fwxp(j,i) = 1.0
717	ELSEIF ( nzb_w_outer(j,i) > nzb_w_outer(j,i-1) ) THEN
718	wall_e_x(j,i) = -1.0 ! left wall (location of adjacent fluid)
719	wall_w_x(j,i) = 1.0
720	fwxm(j,i) = 1.0
721	fwxp(j,i) = 0.0
722	ENDIF
723	!
724	!-- Wall and corner locations inside buildings for limitation of
725	!-- near-wall mixing length l_wall
726	IF ( nzb_s_inner(j,i) > nzb_s_inner(j+1,i) ) THEN
727
728	wall_n(j,i) = nzb_s_inner(j+1,i) + 1 ! North wall
729
730	IF ( nzb_s_inner(j,i) > nzb_s_inner(j,i-1) ) THEN
731	corner_nl(j,i) = MAX( nzb_s_inner(j+1,i), & ! Northleft corner
732	nzb_s_inner(j,i-1) ) + 1
733	ENDIF
734
735	IF ( nzb_s_inner(j,i) > nzb_s_inner(j,i+1) ) THEN
736	corner_nr(j,i) = MAX( nzb_s_inner(j+1,i), & ! Northright corner
737	nzb_s_inner(j,i+1) ) + 1
738	ENDIF
739
740	ENDIF
741
742	IF ( nzb_s_inner(j,i) > nzb_s_inner(j-1,i) ) THEN
743
744	wall_s(j,i) = nzb_s_inner(j-1,i) + 1 ! South wall
745	IF ( nzb_s_inner(j,i) > nzb_s_inner(j,i-1) ) THEN
746	corner_sl(j,i) = MAX( nzb_s_inner(j-1,i), & ! Southleft corner
747	nzb_s_inner(j,i-1) ) + 1
748	ENDIF
749
750	IF ( nzb_s_inner(j,i) > nzb_s_inner(j,i+1) ) THEN
751	corner_sr(j,i) = MAX( nzb_s_inner(j-1,i), & ! Southright corner
752	nzb_s_inner(j,i+1) ) + 1
753	ENDIF
754
755	ENDIF
756
757	IF ( nzb_s_inner(j,i) > nzb_s_inner(j,i-1) ) THEN
758	wall_l(j,i) = nzb_s_inner(j,i-1) + 1 ! Left wall
759	ENDIF
760
761	IF ( nzb_s_inner(j,i) > nzb_s_inner(j,i+1) ) THEN
762	wall_r(j,i) = nzb_s_inner(j,i+1) + 1 ! Right wall
763	ENDIF
764
765	ENDDO
766	ENDDO
767
768	!
769	!-- Calculate wall flag arrays for the multigrid method
770	IF ( psolver == 'multigrid' ) THEN
771	!
772	!-- Gridpoint increment of the current level
773	inc = 1
774
775	DO l = maximum_grid_level, 1 , -1
776
777	nxl_l = nxl_mg(l)
778	nxr_l = nxr_mg(l)
779	nys_l = nys_mg(l)
780	nyn_l = nyn_mg(l)
781	nzt_l = nzt_mg(l)
782
783	!
784	!-- Assign the flag level to be calculated
785	SELECT CASE ( l )
786	CASE ( 1 )
787	flags => wall_flags_1
788	CASE ( 2 )
789	flags => wall_flags_2
790	CASE ( 3 )
791	flags => wall_flags_3
792	CASE ( 4 )
793	flags => wall_flags_4
794	CASE ( 5 )
795	flags => wall_flags_5
796	CASE ( 6 )
797	flags => wall_flags_6
798	CASE ( 7 )
799	flags => wall_flags_7
800	CASE ( 8 )
801	flags => wall_flags_8
802	CASE ( 9 )
803	flags => wall_flags_9
804	CASE ( 10 )
805	flags => wall_flags_10
806	END SELECT
807
808	!
809	!-- Depending on the grid level, set the respective bits in case of
810	!-- neighbouring walls
811	!-- Bit 0: wall to the bottom
812	!-- Bit 1: wall to the top (not realized in remaining PALM code so far)
813	!-- Bit 2: wall to the south
814	!-- Bit 3: wall to the north
815	!-- Bit 4: wall to the left
816	!-- Bit 5: wall to the right
817	!-- Bit 6: inside building
818
819	flags = 0
820
821	DO i = nxl_l-1, nxr_l+1
822	DO j = nys_l-1, nyn_l+1
823	DO k = nzb, nzt_l+1
824
825	!
826	!-- Inside/outside building (inside building does not need
827	!-- further tests for walls)
828	IF ( kinc <= nzb_local(jinc,i*inc) ) THEN
829
830	flags(k,j,i) = IBSET( flags(k,j,i), 6 )
831
832	ELSE
833	!
834	!-- Bottom wall
835	IF ( (k-1)inc <= nzb_local(jinc,i*inc) ) THEN
836	flags(k,j,i) = IBSET( flags(k,j,i), 0 )
837	ENDIF
838	!
839	!-- South wall
840	IF ( kinc <= nzb_local((j-1)inc,i*inc) ) THEN
841	flags(k,j,i) = IBSET( flags(k,j,i), 2 )
842	ENDIF
843	!
844	!-- North wall
845	IF ( kinc <= nzb_local((j+1)inc,i*inc) ) THEN
846	flags(k,j,i) = IBSET( flags(k,j,i), 3 )
847	ENDIF
848	!
849	!-- Left wall
850	IF ( kinc <= nzb_local(jinc,(i-1)*inc) ) THEN
851	flags(k,j,i) = IBSET( flags(k,j,i), 4 )
852	ENDIF
853	!
854	!-- Right wall
855	IF ( kinc <= nzb_local(jinc,(i+1)*inc) ) THEN
856	flags(k,j,i) = IBSET( flags(k,j,i), 5 )
857	ENDIF
858
859	ENDIF
860
861	ENDDO
862	ENDDO
863	ENDDO
864
865	!
866	!-- Test output of flag arrays
867	! i = nxl_l
868	! WRITE (9,*) ' '
869	! WRITE (9,) ' mg level ', l, ' *', mg_switch_to_pe0_level
870	! WRITE (9,*) ' inc=', inc, ' i =', nxl_l
871	! WRITE (9,*) ' nxl_l',nxl_l,' nxr_l=',nxr_l,' nys_l=',nys_l,' nyn_l=',nyn_l
872	! DO k = nzt_l+1, nzb, -1
873	! WRITE (9,'(194(1X,I2))') ( flags(k,j,i), j = nys_l-1, nyn_l+1 )
874	! ENDDO
875
876	inc = inc * 2
877
878	ENDDO
879
880	ENDIF
881
882	!
883	!-- In case of topography: limit near-wall mixing length l_wall further:
884	!-- Go through all points of the subdomain one by one and look for the closest
885	!-- surface
886	IF ( TRIM(topography) /= 'flat' ) THEN
887	DO i = nxl, nxr
888	DO j = nys, nyn
889
890	nzb_si = nzb_s_inner(j,i)
891	vi = vertical_influence(nzb_si)
892
893	IF ( wall_n(j,i) > 0 ) THEN
894	!
895	!-- North wall (y distance)
896	DO k = wall_n(j,i), nzb_si
897	l_wall(k,j+1,i) = MIN( l_wall(k,j+1,i), 0.5 * dy )
898	ENDDO
899	!
900	!-- Above North wall (yz distance)
901	DO k = nzb_si + 1, nzb_si + vi
902	l_wall(k,j+1,i) = MIN( l_wall(k,j+1,i), &
903	SQRT( 0.25 * dy**2 + &
904	( zu(k) - zw(nzb_si) )**2 ) )
905	ENDDO
906	!
907	!-- Northleft corner (xy distance)
908	IF ( corner_nl(j,i) > 0 ) THEN
909	DO k = corner_nl(j,i), nzb_si
910	l_wall(k,j+1,i-1) = MIN( l_wall(k,j+1,i-1), &
911	0.5 * SQRT( dx2 + dy2 ) )
912	ENDDO
913	!
914	!-- Above Northleft corner (xyz distance)
915	DO k = nzb_si + 1, nzb_si + vi
916	l_wall(k,j+1,i-1) = MIN( l_wall(k,j+1,i-1), &
917	SQRT( 0.25 * (dx2 + dy2) + &
918	( zu(k) - zw(nzb_si) )**2 ) )
919	ENDDO
920	ENDIF
921	!
922	!-- Northright corner (xy distance)
923	IF ( corner_nr(j,i) > 0 ) THEN
924	DO k = corner_nr(j,i), nzb_si
925	l_wall(k,j+1,i+1) = MIN( l_wall(k,j+1,i+1), &
926	0.5 * SQRT( dx2 + dy2 ) )
927	ENDDO
928	!
929	!-- Above northright corner (xyz distance)
930	DO k = nzb_si + 1, nzb_si + vi
931	l_wall(k,j+1,i+1) = MIN( l_wall(k,j+1,i+1), &
932	SQRT( 0.25 * (dx2 + dy2) + &
933	( zu(k) - zw(nzb_si) )**2 ) )
934	ENDDO
935	ENDIF
936	ENDIF
937
938	IF ( wall_s(j,i) > 0 ) THEN
939	!
940	!-- South wall (y distance)
941	DO k = wall_s(j,i), nzb_si
942	l_wall(k,j-1,i) = MIN( l_wall(k,j-1,i), 0.5 * dy )
943	ENDDO
944	!
945	!-- Above south wall (yz distance)
946	DO k = nzb_si + 1, &
947	nzb_si + vi
948	l_wall(k,j-1,i) = MIN( l_wall(k,j-1,i), &
949	SQRT( 0.25 * dy**2 + &
950	( zu(k) - zw(nzb_si) )**2 ) )
951	ENDDO
952	!
953	!-- Southleft corner (xy distance)
954	IF ( corner_sl(j,i) > 0 ) THEN
955	DO k = corner_sl(j,i), nzb_si
956	l_wall(k,j-1,i-1) = MIN( l_wall(k,j-1,i-1), &
957	0.5 * SQRT( dx2 + dy2 ) )
958	ENDDO
959	!
960	!-- Above southleft corner (xyz distance)
961	DO k = nzb_si + 1, nzb_si + vi
962	l_wall(k,j-1,i-1) = MIN( l_wall(k,j-1,i-1), &
963	SQRT( 0.25 * (dx2 + dy2) + &
964	( zu(k) - zw(nzb_si) )**2 ) )
965	ENDDO
966	ENDIF
967	!
968	!-- Southright corner (xy distance)
969	IF ( corner_sr(j,i) > 0 ) THEN
970	DO k = corner_sr(j,i), nzb_si
971	l_wall(k,j-1,i+1) = MIN( l_wall(k,j-1,i+1), &
972	0.5 * SQRT( dx2 + dy2 ) )
973	ENDDO
974	!
975	!-- Above southright corner (xyz distance)
976	DO k = nzb_si + 1, nzb_si + vi
977	l_wall(k,j-1,i+1) = MIN( l_wall(k,j-1,i+1), &
978	SQRT( 0.25 * (dx2 + dy2) + &
979	( zu(k) - zw(nzb_si) )**2 ) )
980	ENDDO
981	ENDIF
982
983	ENDIF
984
985	IF ( wall_l(j,i) > 0 ) THEN
986	!
987	!-- Left wall (x distance)
988	DO k = wall_l(j,i), nzb_si
989	l_wall(k,j,i-1) = MIN( l_wall(k,j,i-1), 0.5 * dx )
990	ENDDO
991	!
992	!-- Above left wall (xz distance)
993	DO k = nzb_si + 1, nzb_si + vi
994	l_wall(k,j,i-1) = MIN( l_wall(k,j,i-1), &
995	SQRT( 0.25 * dx**2 + &
996	( zu(k) - zw(nzb_si) )**2 ) )
997	ENDDO
998	ENDIF
999
1000	IF ( wall_r(j,i) > 0 ) THEN
1001	!
1002	!-- Right wall (x distance)
1003	DO k = wall_r(j,i), nzb_si
1004	l_wall(k,j,i+1) = MIN( l_wall(k,j,i+1), 0.5 * dx )
1005	ENDDO
1006	!
1007	!-- Above right wall (xz distance)
1008	DO k = nzb_si + 1, nzb_si + vi
1009	l_wall(k,j,i+1) = MIN( l_wall(k,j,i+1), &
1010	SQRT( 0.25 * dx**2 + &
1011	( zu(k) - zw(nzb_si) )**2 ) )
1012	ENDDO
1013
1014	ENDIF
1015
1016	ENDDO
1017	ENDDO
1018
1019	ENDIF
1020
1021	!
1022	!-- Multiplication with wall_adjustment_factor
1023	l_wall = wall_adjustment_factor * l_wall
1024
1025	!
1026	!-- Need to set lateral boundary conditions for l_wall
1027	CALL exchange_horiz( l_wall )
1028
1029	DEALLOCATE( corner_nl, corner_nr, corner_sl, corner_sr, nzb_local, &
1030	nzb_tmp, vertical_influence, wall_l, wall_n, wall_r, wall_s )
1031
1032
1033	END SUBROUTINE init_grid

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