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module_initialize_squall2d_x.F @ 3026

Last change on this file since 3026 was 11, checked in by aslmd, 15 years ago
spiga@svn-planeto:ajoute le modele meso-echelle martien
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1	!IDEAL:MODEL_LAYER:INITIALIZATION
2	!
3
4	! This MODULE holds the routines which are used to perform various initializations
5	! for the individual domains.
6
7	! This MODULE CONTAINS the following routines:
8
9	! initialize_field_test - 1. Set different fields to different constant
10	! values. This is only a test. If the correct
11	! domain is not found (based upon the "id")
12	! then a fatal error is issued.
13
14	!-----------------------------------------------------------------------
15
16	MODULE module_initialize
17
18	USE module_domain
19	USE module_io_domain
20	USE module_state_description
21	USE module_model_constants
22	USE module_bc
23	USE module_timing
24	USE module_configure
25	USE module_init_utilities
26	#ifdef DM_PARALLEL
27	USE module_dm
28	#endif
29
30
31	CONTAINS
32
33
34	!-------------------------------------------------------------------
35	! this is a wrapper for the solver-specific init_domain routines.
36	! Also dereferences the grid variables and passes them down as arguments.
37	! This is crucial, since the lower level routines may do message passing
38	! and this will get fouled up on machines that insist on passing down
39	! copies of assumed-shape arrays (by passing down as arguments, the
40	! data are treated as assumed-size -- ie. f77 -- arrays and the copying
41	! business is avoided). Fie on the F90 designers. Fie and a pox.
42	! NOTE: Modified to remove all but arrays of rank 4 or more from the
43	! argument list. Arrays with rank>3 are still problematic due to the
44	! above-noted fie- and pox-ities. TBH 20061129.
45
46	SUBROUTINE init_domain ( grid )
47
48	IMPLICIT NONE
49
50	! Input data.
51	TYPE (domain), POINTER :: grid
52	! Local data.
53	INTEGER :: dyn_opt
54	INTEGER :: idum1, idum2
55
56	CALL nl_get_dyn_opt( 1, dyn_opt )
57
58	CALL set_scalar_indices_from_config ( head_grid%id , idum1, idum2 )
59
60	IF ( dyn_opt .eq. 1 &
61	.or. dyn_opt .eq. 2 &
62	.or. dyn_opt .eq. 3 &
63	) THEN
64	CALL init_domain_rk( grid &
65	!
66	#include <em_actual_new_args.inc>
67	!
68	)
69
70	ELSE
71	WRITE(0,*)' init_domain: unknown or unimplemented dyn_opt = ',dyn_opt
72	CALL wrf_error_fatal ( ' init_domain: unknown or unimplemented dyn_opt ' )
73	ENDIF
74
75	END SUBROUTINE init_domain
76
77	!-------------------------------------------------------------------
78
79	SUBROUTINE init_domain_rk ( grid &
80	!
81	# include <em_dummy_new_args.inc>
82	!
83	)
84	IMPLICIT NONE
85
86	! Input data.
87	TYPE (domain), POINTER :: grid
88
89	# include <em_dummy_new_decl.inc>
90
91	TYPE (grid_config_rec_type) :: config_flags
92
93	! Local data
94	INTEGER :: &
95	ids, ide, jds, jde, kds, kde, &
96	ims, ime, jms, jme, kms, kme, &
97	its, ite, jts, jte, kts, kte, &
98	i, j, k
99
100	! Local data
101
102	INTEGER, PARAMETER :: nl_max = 1000
103	REAL, DIMENSION(nl_max) :: zk, p_in, theta, rho, u, v, qv, pd_in
104	INTEGER :: nl_in
105
106
107	INTEGER :: icm,jcm, ii, im1, jj, jm1, loop, error, fid, nxc, nyc
108	REAL :: u_mean,v_mean, f0, p_surf, p_level, qvf, z_at_v, z_at_u
109	REAL :: z_scale, xrad, yrad, zrad, rad, delt, cof1, cof2
110	! REAL, EXTERNAL :: interp_0
111	REAL :: hm
112	REAL :: pi
113
114	! stuff from original initialization that has been dropped from the Registry
115	REAL :: vnu, xnu, xnus, dinit0, cbh, p0_temp, t0_temp, zd, zt
116	REAL :: qvf1, qvf2, pd_surf
117	INTEGER :: it
118	real :: thtmp, ptmp, temp(3)
119
120	LOGICAL :: moisture_init
121	LOGICAL :: stretch_grid, dry_sounding
122
123
124	#ifdef DM_PARALLEL
125	# include <em_data_calls.inc>
126	#endif
127
128
129	SELECT CASE ( model_data_order )
130	CASE ( DATA_ORDER_ZXY )
131	kds = grid%sd31 ; kde = grid%ed31 ;
132	ids = grid%sd32 ; ide = grid%ed32 ;
133	jds = grid%sd33 ; jde = grid%ed33 ;
134
135	kms = grid%sm31 ; kme = grid%em31 ;
136	ims = grid%sm32 ; ime = grid%em32 ;
137	jms = grid%sm33 ; jme = grid%em33 ;
138
139	kts = grid%sp31 ; kte = grid%ep31 ; ! note that tile is entire patch
140	its = grid%sp32 ; ite = grid%ep32 ; ! note that tile is entire patch
141	jts = grid%sp33 ; jte = grid%ep33 ; ! note that tile is entire patch
142	CASE ( DATA_ORDER_XYZ )
143	ids = grid%sd31 ; ide = grid%ed31 ;
144	jds = grid%sd32 ; jde = grid%ed32 ;
145	kds = grid%sd33 ; kde = grid%ed33 ;
146
147	ims = grid%sm31 ; ime = grid%em31 ;
148	jms = grid%sm32 ; jme = grid%em32 ;
149	kms = grid%sm33 ; kme = grid%em33 ;
150
151	its = grid%sp31 ; ite = grid%ep31 ; ! note that tile is entire patch
152	jts = grid%sp32 ; jte = grid%ep32 ; ! note that tile is entire patch
153	kts = grid%sp33 ; kte = grid%ep33 ; ! note that tile is entire patch
154	CASE ( DATA_ORDER_XZY )
155	ids = grid%sd31 ; ide = grid%ed31 ;
156	kds = grid%sd32 ; kde = grid%ed32 ;
157	jds = grid%sd33 ; jde = grid%ed33 ;
158
159	ims = grid%sm31 ; ime = grid%em31 ;
160	kms = grid%sm32 ; kme = grid%em32 ;
161	jms = grid%sm33 ; jme = grid%em33 ;
162
163	its = grid%sp31 ; ite = grid%ep31 ; ! note that tile is entire patch
164	kts = grid%sp32 ; kte = grid%ep32 ; ! note that tile is entire patch
165	jts = grid%sp33 ; jte = grid%ep33 ; ! note that tile is entire patch
166
167	END SELECT
168
169
170	stretch_grid = .true.
171	delt = 3.
172	! z_scale = .50
173	z_scale = .40
174	pi = 2.*asin(1.0)
175	write(6,*) ' pi is ',pi
176	nxc = (ide-ids)/2
177	nyc = jde/2
178
179	CALL model_to_grid_config_rec ( grid%id , model_config_rec , config_flags )
180
181	! here we check to see if the boundary conditions are set properly
182
183	CALL boundary_condition_check( config_flags, bdyzone, error, grid%id )
184
185	moisture_init = .true.
186
187	grid%itimestep=0
188
189	#ifdef DM_PARALLEL
190	CALL wrf_dm_bcast_bytes( icm , IWORDSIZE )
191	CALL wrf_dm_bcast_bytes( jcm , IWORDSIZE )
192	#endif
193
194	CALL nl_set_mminlu(1, ' ')
195	CALL nl_set_iswater(1,0)
196	CALL nl_set_cen_lat(1,40.)
197	CALL nl_set_cen_lon(1,-105.)
198	CALL nl_set_truelat1(1,0.)
199	CALL nl_set_truelat2(1,0.)
200	CALL nl_set_moad_cen_lat (1,0.)
201	CALL nl_set_stand_lon (1,0.)
202	CALL nl_set_map_proj(1,0)
203
204
205	! here we initialize data we currently is not initialized
206	! in the input data
207
208	DO j = jts, jte
209	DO i = its, ite
210	grid%msft(i,j) = 1.
211	grid%msfu(i,j) = 1.
212	grid%msfv(i,j) = 1.
213	grid%sina(i,j) = 0.
214	grid%cosa(i,j) = 1.
215	grid%e(i,j) = 0.
216	grid%f(i,j) = 0.
217
218	END DO
219	END DO
220
221	DO j = jts, jte
222	DO k = kts, kte
223	DO i = its, ite
224	grid%em_ww(i,k,j) = 0.
225	END DO
226	END DO
227	END DO
228
229	grid%step_number = 0
230
231	! set up the grid
232
233	IF (stretch_grid) THEN ! exponential stretch for eta (nearly constant dz)
234	DO k=1, kde
235	grid%em_znw(k) = (exp(-(k-1)/float(kde-1)/z_scale) - exp(-1./z_scale))/ &
236	(1.-exp(-1./z_scale))
237	ENDDO
238	ELSE
239	DO k=1, kde
240	grid%em_znw(k) = 1. - float(k-1)/float(kde-1)
241	ENDDO
242	ENDIF
243
244	DO k=1, kde-1
245	grid%em_dnw(k) = grid%em_znw(k+1) - grid%em_znw(k)
246	grid%em_rdnw(k) = 1./grid%em_dnw(k)
247	grid%em_znu(k) = 0.5*(grid%em_znw(k+1)+grid%em_znw(k))
248	ENDDO
249	DO k=2, kde-1
250	grid%em_dn(k) = 0.5*(grid%em_dnw(k)+grid%em_dnw(k-1))
251	grid%em_rdn(k) = 1./grid%em_dn(k)
252	grid%em_fnp(k) = .5* grid%em_dnw(k )/grid%em_dn(k)
253	grid%em_fnm(k) = .5* grid%em_dnw(k-1)/grid%em_dn(k)
254	ENDDO
255
256	cof1 = (2.grid%em_dn(2)+grid%em_dn(3))/(grid%em_dn(2)+grid%em_dn(3))grid%em_dnw(1)/grid%em_dn(2)
257	cof2 = grid%em_dn(2) /(grid%em_dn(2)+grid%em_dn(3))*grid%em_dnw(1)/grid%em_dn(3)
258	grid%cf1 = grid%em_fnp(2) + cof1
259	grid%cf2 = grid%em_fnm(2) - cof1 - cof2
260	grid%cf3 = cof2
261
262	grid%cfn = (.5*grid%em_dnw(kde-1)+grid%em_dn(kde-1))/grid%em_dn(kde-1)
263	grid%cfn1 = -.5*grid%em_dnw(kde-1)/grid%em_dn(kde-1)
264	grid%rdx = 1./config_flags%dx
265	grid%rdy = 1./config_flags%dy
266
267	! get the sounding from the ascii sounding file, first get dry sounding and
268	! calculate base state
269
270	write(6,*) ' getting dry sounding for base state '
271	dry_sounding = .true.
272	CALL get_sounding( zk, p_in, pd_in, theta, rho, u, v, qv, dry_sounding, nl_max, nl_in )
273
274	write(6,*) ' returned from reading sounding, nl_in is ',nl_in
275
276	! find ptop for the desired ztop (ztop is input from the namelist),
277	! and find surface pressure
278
279	grid%p_top = interp_0( p_in, zk, config_flags%ztop, nl_in )
280
281	DO j=jts,jte
282	DO i=its,ite ! flat surface
283	grid%em_phb(i,1,j) = 0.
284	grid%em_php(i,1,j) = 0.
285	grid%em_ph0(i,1,j) = 0.
286	grid%ht(i,j) = 0.
287	ENDDO
288	ENDDO
289
290	DO J = jts, jte
291	DO I = its, ite
292
293	p_surf = interp_0( p_in, zk, grid%em_phb(i,1,j)/g, nl_in )
294	grid%em_mub(i,j) = p_surf-grid%p_top
295
296	! this is dry hydrostatic sounding (base state), so given grid%em_p (coordinate),
297	! interp theta (from interp) and compute 1/rho from eqn. of state
298
299	DO K = 1, kte-1
300	p_level = grid%em_znu(k)*(p_surf - grid%p_top) + grid%p_top
301	grid%em_pb(i,k,j) = p_level
302	grid%em_t_init(i,k,j) = interp_0( theta, p_in, p_level, nl_in ) - t0
303	grid%em_alb(i,k,j) = (r_d/p1000mb)(grid%em_t_init(i,k,j)+t0)(grid%em_pb(i,k,j)/p1000mb)**cvpm
304	ENDDO
305
306	! calc hydrostatic balance (alternatively we could interp the geopotential from the
307	! sounding, but this assures that the base state is in exact hydrostatic balance with
308	! respect to the model eqns.
309
310	DO k = 2,kte
311	grid%em_phb(i,k,j) = grid%em_phb(i,k-1,j) - grid%em_dnw(k-1)grid%em_mub(i,j)grid%em_alb(i,k-1,j)
312	ENDDO
313
314	ENDDO
315	ENDDO
316
317	write(6,*) ' ptop is ',grid%p_top
318	write(6,*) ' base state grid%em_mub(1,1), p_surf is ',grid%em_mub(1,1),grid%em_mub(1,1)+grid%p_top
319
320	! calculate full state for each column - this includes moisture.
321
322	write(6,*) ' getting moist sounding for full state '
323	dry_sounding = .false.
324	CALL get_sounding( zk, p_in, pd_in, theta, rho, u, v, qv, dry_sounding, nl_max, nl_in )
325
326	DO J = jts, min(jde-1,jte)
327	DO I = its, min(ide-1,ite)
328
329	! At this point grid%p_top is already set. find the DRY mass in the column
330	! by interpolating the DRY pressure.
331
332	pd_surf = interp_0( pd_in, zk, grid%em_phb(i,1,j)/g, nl_in )
333
334	! compute the perturbation mass and the full mass
335
336	grid%em_mu_1(i,j) = pd_surf-grid%p_top - grid%em_mub(i,j)
337	grid%em_mu_2(i,j) = grid%em_mu_1(i,j)
338	grid%em_mu0(i,j) = grid%em_mu_1(i,j) + grid%em_mub(i,j)
339
340	! given the dry pressure and coordinate system, interp the potential
341	! temperature and qv
342
343	do k=1,kde-1
344
345	p_level = grid%em_znu(k)*(pd_surf - grid%p_top) + grid%p_top
346
347	moist(i,k,j,P_QV) = interp_0( qv, pd_in, p_level, nl_in )
348	grid%em_t_1(i,k,j) = interp_0( theta, pd_in, p_level, nl_in ) - t0
349	grid%em_t_2(i,k,j) = grid%em_t_1(i,k,j)
350
351
352	enddo
353
354	! integrate the hydrostatic equation (from the RHS of the bigstep
355	! vertical momentum equation) down from the top to get grid%em_p.
356	! first from the top of the model to the top pressure
357
358	k = kte-1 ! top level
359
360	qvf1 = 0.5*(moist(i,k,j,P_QV)+moist(i,k,j,P_QV))
361	qvf2 = 1./(1.+qvf1)
362	qvf1 = qvf1*qvf2
363
364	! grid%em_p(i,k,j) = - 0.5*grid%em_mu_1(i,j)/grid%em_rdnw(k)
365	grid%em_p(i,k,j) = - 0.5(grid%em_mu_1(i,j)+qvf1grid%em_mub(i,j))/grid%em_rdnw(k)/qvf2
366	qvf = 1. + rvovrd*moist(i,k,j,P_QV)
367	grid%em_alt(i,k,j) = (r_d/p1000mb)(grid%em_t_1(i,k,j)+t0)qvf* &
368	(((grid%em_p(i,k,j)+grid%em_pb(i,k,j))/p1000mb)**cvpm)
369	grid%em_al(i,k,j) = grid%em_alt(i,k,j) - grid%em_alb(i,k,j)
370
371	! down the column
372
373	do k=kte-2,1,-1
374	qvf1 = 0.5*(moist(i,k,j,P_QV)+moist(i,k+1,j,P_QV))
375	qvf2 = 1./(1.+qvf1)
376	qvf1 = qvf1*qvf2
377	grid%em_p(i,k,j) = grid%em_p(i,k+1,j) - (grid%em_mu_1(i,j) + qvf1*grid%em_mub(i,j))/qvf2/grid%em_rdn(k+1)
378	qvf = 1. + rvovrd*moist(i,k,j,P_QV)
379	grid%em_alt(i,k,j) = (r_d/p1000mb)(grid%em_t_1(i,k,j)+t0)qvf* &
380	(((grid%em_p(i,k,j)+grid%em_pb(i,k,j))/p1000mb)**cvpm)
381	grid%em_al(i,k,j) = grid%em_alt(i,k,j) - grid%em_alb(i,k,j)
382	enddo
383
384	! this is the hydrostatic equation used in the model after the
385	! small timesteps. In the model, grid%em_al (inverse density)
386	! is computed from the geopotential.
387
388
389	grid%em_ph_1(i,1,j) = 0.
390	DO k = 2,kte
391	grid%em_ph_1(i,k,j) = grid%em_ph_1(i,k-1,j) - (1./grid%em_rdnw(k-1))*( &
392	(grid%em_mub(i,j)+grid%em_mu_1(i,j))*grid%em_al(i,k-1,j)+ &
393	grid%em_mu_1(i,j)*grid%em_alb(i,k-1,j) )
394
395	grid%em_ph_2(i,k,j) = grid%em_ph_1(i,k,j)
396	grid%em_ph0(i,k,j) = grid%em_ph_1(i,k,j) + grid%em_phb(i,k,j)
397	ENDDO
398
399	if((i==2) .and. (j==2)) then
400	write(6,*) ' grid%em_ph_1 calc ',grid%em_ph_1(2,1,2),grid%em_ph_1(2,2,2),&
401	grid%em_mu_1(2,2)+grid%em_mub(2,2),grid%em_mu_1(2,2), &
402	grid%em_alb(2,1,2),grid%em_al(1,2,1),grid%em_rdnw(1)
403	endif
404
405	ENDDO
406	ENDDO
407
408	!#if 0
409
410	! thermal perturbation to kick off convection
411
412	write(6,*) ' nxc, nyc for perturbation ',nxc,nyc
413	write(6,*) ' delt for perturbation ',delt
414
415	DO J = jts, min(jde-1,jte)
416	! yrad = config_flags%dy*float(j-nyc)/4000.
417	yrad = 0.
418	DO I = its, min(ide-1,ite)
419	xrad = config_flags%dx*float(i-nxc)/4000.
420	! xrad = 0.
421	DO K = 1, kte-1
422
423	! put in preturbation theta (bubble) and recalc density. note,
424	! the mass in the column is not changing, so when theta changes,
425	! we recompute density and geopotential
426
427	zrad = 0.5*(grid%em_ph_1(i,k,j)+grid%em_ph_1(i,k+1,j) &
428	+grid%em_phb(i,k,j)+grid%em_phb(i,k+1,j))/g
429	zrad = (zrad-1500.)/1500.
430	RAD=SQRT(xradxrad+yradyrad+zrad*zrad)
431	IF(RAD <= 1.) THEN
432	grid%em_t_1(i,k,j)=grid%em_t_1(i,k,j)+deltCOS(.5PIRAD)*2
433	grid%em_t_2(i,k,j)=grid%em_t_1(i,k,j)
434	qvf = 1. + rvovrd*moist(i,k,j,P_QV)
435	grid%em_alt(i,k,j) = (r_d/p1000mb)(grid%em_t_1(i,k,j)+t0)qvf* &
436	(((grid%em_p(i,k,j)+grid%em_pb(i,k,j))/p1000mb)**cvpm)
437	grid%em_al(i,k,j) = grid%em_alt(i,k,j) - grid%em_alb(i,k,j)
438	ENDIF
439	ENDDO
440
441	! rebalance hydrostatically
442
443	DO k = 2,kte
444	grid%em_ph_1(i,k,j) = grid%em_ph_1(i,k-1,j) - (1./grid%em_rdnw(k-1))*( &
445	(grid%em_mub(i,j)+grid%em_mu_1(i,j))*grid%em_al(i,k-1,j)+ &
446	grid%em_mu_1(i,j)*grid%em_alb(i,k-1,j) )
447
448	grid%em_ph_2(i,k,j) = grid%em_ph_1(i,k,j)
449	grid%em_ph0(i,k,j) = grid%em_ph_1(i,k,j) + grid%em_phb(i,k,j)
450	ENDDO
451
452	ENDDO
453	ENDDO
454
455	!#endif
456
457	write(6,*) ' grid%em_mu_1 from comp ', grid%em_mu_1(1,1)
458	write(6,*) ' full state sounding from comp, ph, grid%em_p, grid%em_al, grid%em_t_1, qv '
459	do k=1,kde-1
460	write(6,'(i3,1x,5(1x,1pe10.3))') k, grid%em_ph_1(1,k,1)+grid%em_phb(1,k,1), &
461	grid%em_p(1,k,1)+grid%em_pb(1,k,1), grid%em_alt(1,k,1), &
462	grid%em_t_1(1,k,1)+t0, moist(1,k,1,P_QV)
463	enddo
464
465	write(6,*) ' pert state sounding from comp, grid%em_ph_1, pp, alp, grid%em_t_1, qv '
466	do k=1,kde-1
467	write(6,'(i3,1x,5(1x,1pe10.3))') k, grid%em_ph_1(1,k,1), &
468	grid%em_p(1,k,1), grid%em_al(1,k,1), &
469	grid%em_t_1(1,k,1), moist(1,k,1,P_QV)
470	enddo
471
472	! interp v
473
474	DO J = jts, jte
475	DO I = its, min(ide-1,ite)
476
477	IF (j == jds) THEN
478	z_at_v = grid%em_phb(i,1,j)/g
479	ELSE IF (j == jde) THEN
480	z_at_v = grid%em_phb(i,1,j-1)/g
481	ELSE
482	z_at_v = 0.5*(grid%em_phb(i,1,j)+grid%em_phb(i,1,j-1))/g
483	END IF
484
485	p_surf = interp_0( p_in, zk, z_at_v, nl_in )
486
487	DO K = 1, kte
488	p_level = grid%em_znu(k)*(p_surf - grid%p_top) + grid%p_top
489	grid%em_v_1(i,k,j) = interp_0( v, p_in, p_level, nl_in )
490	grid%em_v_2(i,k,j) = grid%em_v_1(i,k,j)
491	ENDDO
492
493	ENDDO
494	ENDDO
495
496	! interp u
497
498	DO J = jts, min(jde-1,jte)
499	DO I = its, ite
500
501	IF (i == ids) THEN
502	z_at_u = grid%em_phb(i,1,j)/g
503	ELSE IF (i == ide) THEN
504	z_at_u = grid%em_phb(i-1,1,j)/g
505	ELSE
506	z_at_u = 0.5*(grid%em_phb(i,1,j)+grid%em_phb(i-1,1,j))/g
507	END IF
508
509	p_surf = interp_0( p_in, zk, z_at_u, nl_in )
510
511	DO K = 1, kte
512	p_level = grid%em_znu(k)*(p_surf - grid%p_top) + grid%p_top
513	grid%em_u_1(i,k,j) = interp_0( u, p_in, p_level, nl_in )
514	grid%em_u_2(i,k,j) = grid%em_u_1(i,k,j)
515	ENDDO
516
517	ENDDO
518	ENDDO
519
520	! set w
521
522	DO J = jts, min(jde-1,jte)
523	DO K = kts, kte
524	DO I = its, min(ide-1,ite)
525	grid%em_w_1(i,k,j) = 0.
526	grid%em_w_2(i,k,j) = 0.
527	ENDDO
528	ENDDO
529	ENDDO
530
531	! set a few more things
532
533	DO J = jts, min(jde-1,jte)
534	DO K = kts, kte-1
535	DO I = its, min(ide-1,ite)
536	grid%h_diabatic(i,k,j) = 0.
537	ENDDO
538	ENDDO
539	ENDDO
540
541	DO k=1,kte-1
542	grid%em_t_base(k) = grid%em_t_1(1,k,1)
543	grid%qv_base(k) = moist(1,k,1,P_QV)
544	grid%u_base(k) = grid%em_u_1(1,k,1)
545	grid%v_base(k) = grid%em_v_1(1,k,1)
546	grid%z_base(k) = 0.5*(grid%em_phb(1,k,1)+grid%em_phb(1,k+1,1)+grid%em_ph_1(1,k,1)+grid%em_ph_1(1,k+1,1))/g
547	ENDDO
548
549	DO J = jts, min(jde-1,jte)
550	DO I = its, min(ide-1,ite)
551	thtmp = grid%em_t_2(i,1,j)+t0
552	ptmp = grid%em_p(i,1,j)+grid%em_pb(i,1,j)
553	temp(1) = thtmp * (ptmp/p1000mb)**rcp
554	thtmp = grid%em_t_2(i,2,j)+t0
555	ptmp = grid%em_p(i,2,j)+grid%em_pb(i,2,j)
556	temp(2) = thtmp * (ptmp/p1000mb)**rcp
557	thtmp = grid%em_t_2(i,3,j)+t0
558	ptmp = grid%em_p(i,3,j)+grid%em_pb(i,3,j)
559	temp(3) = thtmp * (ptmp/p1000mb)**rcp
560
561	grid%tsk(I,J)=grid%cf1temp(1)+grid%cf2temp(2)+grid%cf3*temp(3)
562	grid%tmn(I,J)=grid%tsk(I,J)-0.5
563	ENDDO
564	ENDDO
565
566	RETURN
567
568	END SUBROUTINE init_domain_rk
569
570	SUBROUTINE init_module_initialize
571	END SUBROUTINE init_module_initialize
572
573	!---------------------------------------------------------------------
574
575	! test driver for get_sounding
576	!
577	! implicit none
578	! integer n
579	! parameter(n = 1000)
580	! real zk(n),p(n),theta(n),rho(n),u(n),v(n),qv(n),pd(n)
581	! logical dry
582	! integer nl,k
583	!
584	! dry = .false.
585	! dry = .true.
586	! call get_sounding( zk, p, pd, theta, rho, u, v, qv, dry, n, nl )
587	! write(6,*) ' input levels ',nl
588	! write(6,*) ' sounding '
589	! write(6,*) ' k height(m) press (Pa) pd(Pa) theta (K) den(kg/m^3) u(m/s) v(m/s) qv(g/g) '
590	! do k=1,nl
591	! write(6,'(1x,i3,8(1x,1pe10.3))') k, zk(k), p(k), pd(k), theta(k), rho(k), u(k), v(k), qv(k)
592	! enddo
593	! end
594	!
595	!---------------------------------------------------------------------------
596
597	subroutine get_sounding( zk, p, p_dry, theta, rho, &
598	u, v, qv, dry, nl_max, nl_in )
599	implicit none
600
601	integer nl_max, nl_in
602	real zk(nl_max), p(nl_max), theta(nl_max), rho(nl_max), &
603	u(nl_max), v(nl_max), qv(nl_max), p_dry(nl_max)
604	logical dry
605
606	integer n
607	parameter(n=1000)
608	logical debug
609	parameter( debug = .true.)
610
611	! input sounding data
612
613	real p_surf, th_surf, qv_surf
614	real pi_surf, pi(n)
615	real h_input(n), th_input(n), qv_input(n), u_input(n), v_input(n)
616
617	! diagnostics
618
619	real rho_surf, p_input(n), rho_input(n)
620	real pm_input(n) ! this are for full moist sounding
621
622	! local data
623
624	real p1000mb,cv,cp,r,cvpm,g
625	parameter (p1000mb = 1.e+05, r = 287, cp = 1003., cv = cp-r, cvpm = -cv/cp, g=9.81 )
626	integer k, it, nl
627	real qvf, qvf1, dz
628
629	! first, read the sounding
630
631	call read_sounding( p_surf, th_surf, qv_surf, &
632	h_input, th_input, qv_input, u_input, v_input,n, nl, debug )
633
634	if(dry) then
635	do k=1,nl
636	qv_input(k) = 0.
637	enddo
638	endif
639
640	if(debug) write(6,*) ' number of input levels = ',nl
641
642	nl_in = nl
643	if(nl_in .gt. nl_max ) then
644	write(6,*) ' too many levels for input arrays ',nl_in,nl_max
645	call wrf_error_fatal ( ' too many levels for input arrays ' )
646	end if
647
648	! compute diagnostics,
649	! first, convert qv(g/kg) to qv(g/g)
650
651	do k=1,nl
652	qv_input(k) = 0.001*qv_input(k)
653	enddo
654
655	p_surf = 100.*p_surf ! convert to pascals
656	qvf = 1. + rvovrd*qv_input(1)
657	rho_surf = 1./((r/p1000mb)th_surfqvf((p_surf/p1000mb)*cvpm))
658	pi_surf = (p_surf/p1000mb)**(r/cp)
659
660	if(debug) then
661	write(6,*) ' surface density is ',rho_surf
662	write(6,*) ' surface pi is ',pi_surf
663	end if
664
665
666	! integrate moist sounding hydrostatically, starting from the
667	! specified surface pressure
668	! -> first, integrate from surface to lowest level
669
670	qvf = 1. + rvovrd*qv_input(1)
671	qvf1 = 1. + qv_input(1)
672	rho_input(1) = rho_surf
673	dz = h_input(1)
674	do it=1,10
675	pm_input(1) = p_surf &
676	- 0.5dz(rho_surf+rho_input(1))gqvf1
677	rho_input(1) = 1./((r/p1000mb)th_input(1)qvf((pm_input(1)/p1000mb)*cvpm))
678	enddo
679
680	! integrate up the column
681
682	do k=2,nl
683	rho_input(k) = rho_input(k-1)
684	dz = h_input(k)-h_input(k-1)
685	qvf1 = 0.5*(2.+(qv_input(k-1)+qv_input(k)))
686	qvf = 1. + rvovrd*qv_input(k) ! qv is in g/kg here
687
688	do it=1,10
689	pm_input(k) = pm_input(k-1) &
690	- 0.5dz(rho_input(k)+rho_input(k-1))gqvf1
691	rho_input(k) = 1./((r/p1000mb)th_input(k)qvf((pm_input(k)/p1000mb)*cvpm))
692	enddo
693	enddo
694
695	! we have the moist sounding
696
697	! next, compute the dry sounding using p at the highest level from the
698	! moist sounding and integrating down.
699
700	p_input(nl) = pm_input(nl)
701
702	do k=nl-1,1,-1
703	dz = h_input(k+1)-h_input(k)
704	p_input(k) = p_input(k+1) + 0.5dz(rho_input(k)+rho_input(k+1))*g
705	enddo
706
707
708	do k=1,nl
709
710	zk(k) = h_input(k)
711	p(k) = pm_input(k)
712	p_dry(k) = p_input(k)
713	theta(k) = th_input(k)
714	rho(k) = rho_input(k)
715	u(k) = u_input(k)
716	v(k) = v_input(k)
717	qv(k) = qv_input(k)
718
719	enddo
720
721	if(debug) then
722	write(6,*) ' sounding '
723	write(6,*) ' k height(m) press (Pa) pd(Pa) theta (K) den(kg/m^3) u(m/s) v(m/s) qv(g/g) '
724	do k=1,nl
725	write(6,'(1x,i3,8(1x,1pe10.3))') k, zk(k), p(k), p_dry(k), theta(k), rho(k), u(k), v(k), qv(k)
726	enddo
727
728	end if
729
730	end subroutine get_sounding
731
732	!-------------------------------------------------------
733
734	subroutine read_sounding( ps,ts,qvs,h,th,qv,u,v,n,nl,debug )
735	implicit none
736	integer n,nl
737	real ps,ts,qvs,h(n),th(n),qv(n),u(n),v(n)
738	logical end_of_file
739	logical debug
740
741	integer k
742
743	open(unit=10,file='input_sounding',form='formatted',status='old')
744	rewind(10)
745	read(10,*) ps, ts, qvs
746	if(debug) then
747	write(6,*) ' input sounding surface parameters '
748	write(6,*) ' surface pressure (mb) ',ps
749	write(6,*) ' surface pot. temp (K) ',ts
750	write(6,*) ' surface mixing ratio (g/kg) ',qvs
751	end if
752
753	end_of_file = .false.
754	k = 0
755
756	do while (.not. end_of_file)
757
758	read(10,*,end=100) h(k+1), th(k+1), qv(k+1), u(k+1), v(k+1)
759	k = k+1
760	if(debug) write(6,'(1x,i3,5(1x,e10.3))') k, h(k), th(k), qv(k), u(k), v(k)
761	go to 110
762	100 end_of_file = .true.
763	110 continue
764	enddo
765
766	nl = k
767
768	close(unit=10,status = 'keep')
769
770	end subroutine read_sounding
771
772	END MODULE module_initialize

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