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init_grid.f90 @ 91

Last change on this file since 91 was 77, checked in by raasch, 18 years ago

New:
---

particle reflection from vertical walls implemented, particle SGS model adjusted to walls

Wall functions for vertical walls now include diabatic conditions. New subroutines wall_fluxes, wall_fluxes_e. New 4D-array rif_wall.

new d3par-parameter netcdf_64bit_3d to switch on 64bit offset only for 3D files

new d3par-parameter dt_max to define the maximum value for the allowed timestep

new inipar-parameter loop_optimization to control the loop optimization method

new inipar-parameter pt_refrence. If given, this value is used as the reference that in buoyancy terms (otherwise, the instantaneous horizontally averaged temperature is used).

new user interface user_advec_particles

new initializing action "by_user" calls user_init_3d_model and allows the initial setting of all 3d arrays

topography height informations are stored on arrays zu_s_inner and zw_w_inner and output to the 2d/3d NetCDF files

samples added to the user interface which show how to add user-define time series quantities.

calculation/output of precipitation amount, precipitation rate and z0 (by setting "pra*", "prr*", "z0*" with data_output). The time interval on which the precipitation amount is defined is set by new d3par-parameter precipitation_amount_interval

unit 9 opened for debug output (file DEBUG_<pe#>)

Makefile, advec_particles, average_3d_data, buoyancy, calc_precipitation, check_open, check_parameters, data_output_2d, diffusion_e, diffusion_u, diffusion_v, diffusion_w, diffusivities, header, impact_of_latent_heat, init_particles, init_3d_model, modules, netcdf, parin, production_e, read_var_list, read_3d_binary, sum_up_3d_data, user_interface, write_var_list, write_3d_binary

New: wall_fluxes

Changed:

General revision of non-cyclic horizontal boundary conditions: radiation boundary conditions are now used instead of Neumann conditions at the outflow (calculation needs velocity values for t-dt, which are stored on new arrays u_m_l, u_m_r, etc.), calculation of mean outflow is not needed any more, volume flow control is added for the outflow boundary (currently only for the north boundary!!), additional gridpoints along x and y (uxrp, vynp) are not needed any more, routine "boundary_conds" now operates on timelevel t+dt and is not split in two parts (main, uvw_outflow) any more, Neumann boundary conditions at inflow/outflow in case of non-cyclic boundary conditions for all 2d-arrays that are handled by exchange_horiz_2d

The FFT-method for solving the Poisson-equation is now working with Neumann boundary conditions both at the bottom and the top. This requires adjustments of the tridiagonal coefficients and subtracting the horizontally averaged mean from the vertical velocity field.

+age_m in particle_type

Particles-package is now part of the default code ("-p particles" is not needed any more).

Move call of user_actions( 'after_integration' ) below increment of times
and counters. user_actions is now called for each statistic region and has as an argument the number of the respective region (sr)

d3par-parameter data_output_ts removed. Timeseries output for "profil" removed. Timeseries are now switched on by dt_dots. Timeseries data is collected in flow_statistics.

Initial velocities at nzb+1 are regarded for volume flow control in case they have been set zero before (to avoid small timesteps); see new internal parameters u/v_nzb_p1_for_vfc.

q is not allowed to become negative (prognostic_equations).

poisfft_init is only called if fft-solver is switched on (init_pegrid).

d3par-parameter moisture renamed to humidity.

Subversion global revision number is read from mrun and added to the run description header and to the run control (_rc) file.

vtk directives removed from main program.

The uitility routine interpret_config reads PALM environment variables from NAMELIST instead using the system call GETENV.

advec_u_pw, advec_u_up, advec_v_pw, advec_v_up, asselin_filter, check_parameters, coriolis, data_output_dvrp, data_output_ptseries, data_output_ts, data_output_2d, data_output_3d, diffusion_u, diffusion_v, exchange_horiz, exchange_horiz_2d, flow_statistics, header, init_grid, init_particles, init_pegrid, init_rankine, init_pt_anomaly, init_1d_model, init_3d_model, modules, palm, package_parin, parin, poisfft, poismg, prandtl_fluxes, pres, production_e, prognostic_equations, read_var_list, read_3d_binary, sor, swap_timelevel, time_integration, write_var_list, write_3d_binary

Errors:

Bugfix: preset of tendencies te_em, te_um, te_vm in init_1d_model

Bugfix in sample for reading user defined data from restart file (user_init)

Bugfix in setting diffusivities for cases with the outflow damping layer extending over more than one subdomain (init_3d_model)

Check for possible negative humidities in the initial humidity profile.

in Makefile, default suffixes removed from the suffix list to avoid calling of m2c in
# case of .mod files

Makefile
check_parameters, init_1d_model, init_3d_model, user_interface

Property svn:keywords set to Id

File size: 29.6 KB

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

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source: palm/trunk/SOURCE/init_grid.f90 @ 91

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