source: lmdz_wrf/trunk/WRFV3/share/dfi.F @ 1939

Last change on this file since 1939 was 1, checked in by lfita, 10 years ago
  • -- --- Opening of the WRF+LMDZ coupling repository --- -- -

WRF: version v3.3
LMDZ: version v1818

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1   SUBROUTINE dfi_accumulate( grid )
2
3      USE module_domain, ONLY : domain
4!      USE module_configure
5      USE module_driver_constants
6      USE module_machine
7!      USE module_dm
8      USE module_model_constants
9      USE module_state_description
10
11      IMPLICIT NONE
12
13      REAL hn
14      CHARACTER*80 mess
15
16      !  Input data.
17
18      TYPE(domain) , POINTER          :: grid
19
20      IF ( grid%dfi_opt .EQ. DFI_NODFI .OR. grid%dfi_stage .EQ. DFI_FST ) RETURN
21
22#if (EM_CORE == 1)
23
24
25      hn = grid%hcoeff(grid%itimestep+1)
26
27      ! accumulate dynamic variables
28       grid%dfi_mu(:,:)    = grid%dfi_mu(:,:)    + grid%mu_2(:,:)    * hn
29       grid%dfi_u(:,:,:)   = grid%dfi_u(:,:,:)   + grid%u_2(:,:,:)   * hn
30       grid%dfi_v(:,:,:)   = grid%dfi_v(:,:,:)   + grid%v_2(:,:,:)   * hn
31       grid%dfi_w(:,:,:)   = grid%dfi_w(:,:,:)   + grid%w_2(:,:,:)   * hn
32       grid%dfi_ww(:,:,:)  = grid%dfi_ww(:,:,:)  + grid%ww(:,:,:)    * hn
33       grid%dfi_t(:,:,:)   = grid%dfi_t(:,:,:)   + grid%t_2(:,:,:)   * hn
34       grid%dfi_phb(:,:,:) = grid%dfi_phb(:,:,:) + grid%phb(:,:,:)   * hn
35       grid%dfi_ph0(:,:,:) = grid%dfi_ph0(:,:,:) + grid%ph0(:,:,:)   * hn
36       grid%dfi_php(:,:,:) = grid%dfi_php(:,:,:) + grid%php(:,:,:)   * hn
37       grid%dfi_p(:,:,:)   = grid%dfi_p(:,:,:)   + grid%p(:,:,:)     * hn
38       grid%dfi_ph(:,:,:)  = grid%dfi_ph(:,:,:)  + grid%ph_2(:,:,:)  * hn
39       grid%dfi_tke(:,:,:) = grid%dfi_tke(:,:,:) + grid%tke_2(:,:,:) * hn
40       grid%dfi_al(:,:,:)  = grid%dfi_al(:,:,:)  + grid%al(:,:,:)    * hn
41       grid%dfi_alt(:,:,:) = grid%dfi_alt(:,:,:) + grid%alt(:,:,:)   * hn
42       grid%dfi_pb(:,:,:)  = grid%dfi_pb(:,:,:)  + grid%pb(:,:,:)    * hn
43      ! neg. check on hydrometeor and scalar variables
44       grid%moist(:,:,:,:) = max(0.,grid%moist(:,:,:,:))
45       grid%dfi_scalar(:,:,:,:) = max(0.,grid%dfi_scalar(:,:,:,:))
46#if ( WRF_DFI_RADAR == 1 )
47     IF ( grid%dfi_radar .EQ. 0 ) then 
48       grid%dfi_moist(:,:,:,:)  = grid%dfi_moist(:,:,:,:)  + grid%moist(:,:,:,:)  * hn
49     ELSE
50       grid%dfi_moist(:,:,:,P_QV) = grid%dfi_moist(:,:,:,P_QV) + grid%moist(:,:,:,P_QV) * hn
51     ENDIF
52#else
53       grid%dfi_moist(:,:,:,:)  = grid%dfi_moist(:,:,:,:)  + grid%moist(:,:,:,:)  * hn
54#endif
55       grid%dfi_scalar(:,:,:,:) = grid%dfi_scalar(:,:,:,:) + grid%scalar(:,:,:,:) * hn
56
57      ! accumulate DFI coefficient
58      grid%hcoeff_tot = grid%hcoeff_tot + hn
59#endif
60
61#if (NMM_CORE == 1)
62      hn = grid%hcoeff(grid%ntsd+1)
63      grid%dfi_pd(:,:)    = grid%dfi_pd(:,:)    + grid%pd(:,:)    * hn
64      grid%dfi_pint(:,:,:)   = grid%dfi_pint(:,:,:)   + grid%pint(:,:,:)   * hn
65      grid%dfi_dwdt(:,:,:)   = grid%dfi_dwdt(:,:,:)   + grid%dwdt(:,:,:)   * hn
66      grid%dfi_t(:,:,:)   = grid%dfi_t(:,:,:)   + grid%t(:,:,:)   * hn
67      grid%dfi_q(:,:,:)   = grid%dfi_q(:,:,:)   + grid%q(:,:,:)   * hn
68      grid%dfi_q2(:,:,:)  = grid%dfi_q2(:,:,:)  + grid%q2(:,:,:)  * hn
69      grid%dfi_cwm(:,:,:) = grid%dfi_cwm(:,:,:) + grid%cwm(:,:,:) * hn
70      grid%dfi_u(:,:,:)   = grid%dfi_u(:,:,:)   + grid%u(:,:,:)   * hn
71      grid%dfi_v(:,:,:)   = grid%dfi_v(:,:,:)   + grid%v(:,:,:)   * hn
72      grid%dfi_moist(:,:,:,:)  = grid%dfi_moist(:,:,:,:)  + grid%moist(:,:,:,:)  * hn
73      grid%dfi_scalar(:,:,:,:) = grid%dfi_scalar(:,:,:,:) + grid%scalar(:,:,:,:) * hn
74      ! accumulate DFI coefficient
75      grid%hcoeff_tot = grid%hcoeff_tot + hn
76      write(mess,*) 'grid%hcoeff_tot: ', grid%hcoeff_tot
77      call wrf_message(mess)
78#endif
79
80   END SUBROUTINE dfi_accumulate
81
82   SUBROUTINE dfi_bck_init ( grid )
83
84      USE module_domain, ONLY : domain, head_grid, domain_get_stop_time, domain_get_start_time
85      USE module_utility
86      USE module_state_description
87
88      IMPLICIT NONE
89
90      TYPE (domain) , POINTER                 :: grid
91      INTEGER rc
92      CHARACTER*80 mess
93
94      INTERFACE
95         SUBROUTINE Setup_Timekeeping(grid)
96            USE module_domain, ONLY : domain
97            TYPE (domain), POINTER :: grid
98         END SUBROUTINE Setup_Timekeeping
99
100         SUBROUTINE dfi_save_arrays(grid)
101            USE module_domain, ONLY : domain
102            TYPE (domain), POINTER :: grid
103         END SUBROUTINE dfi_save_arrays
104
105         SUBROUTINE dfi_clear_accumulation(grid)
106            USE module_domain, ONLY : domain
107            TYPE (domain), POINTER :: grid
108         END SUBROUTINE dfi_clear_accumulation
109
110         SUBROUTINE optfil_driver(grid)
111            USE module_domain, ONLY : domain
112            TYPE (domain), POINTER :: grid
113         END SUBROUTINE optfil_driver
114
115         SUBROUTINE start_domain(grid, allowed_to_read)
116            USE module_domain, ONLY : domain
117            TYPE (domain)          :: grid
118            LOGICAL, INTENT(IN)    :: allowed_to_read
119         END SUBROUTINE start_domain
120      END INTERFACE
121
122      grid%dfi_stage = DFI_BCK
123
124      ! Negate time step
125      IF ( grid%time_step_dfi .gt. 0 ) THEN
126        CALL nl_set_time_step ( 1, -grid%time_step_dfi )
127      ELSE
128        CALL nl_set_time_step ( 1, -grid%time_step )
129        CALL nl_set_time_step_fract_num ( 1, -grid%time_step_fract_num )
130      ENDIF
131
132      CALL Setup_Timekeeping (grid)
133
134      ! set physics options to zero
135      CALL nl_set_mp_physics( grid%id, 0 )
136      CALL nl_set_ra_lw_physics( grid%id, 0 )
137      CALL nl_set_ra_sw_physics( grid%id, 0 )
138      CALL nl_set_sf_surface_physics( grid%id, 0 )
139      CALL nl_set_sf_sfclay_physics( grid%id, 0 )
140      CALL nl_set_sf_urban_physics( grid%id, 0 )
141      CALL nl_set_bl_pbl_physics( grid%id, 0 )
142      CALL nl_set_cu_physics( grid%id, 0 )
143      CALL nl_set_damp_opt( grid%id, 0 )
144      CALL nl_set_sst_update( grid%id, 0 )
145      CALL nl_set_fractional_seaice( grid%id, 0 )
146      CALL nl_set_gwd_opt( grid%id, 0 )
147      CALL nl_set_feedback( grid%id, 0 )
148      ! set bc
149#if (EM_CORE == 1)
150      CALL nl_set_diff_6th_opt( grid%id, 0 )
151      CALL nl_set_constant_bc(1, grid%constant_bc)
152      CALL nl_set_use_adaptive_time_step( grid%id, .false. )
153#endif
154
155#ifdef WRF_CHEM
156      ! set chemistry option to zero
157      CALL nl_set_chem_opt (grid%id, 0)
158      CALL nl_set_aer_ra_feedback (grid%id, 0)
159      CALL nl_set_io_form_auxinput5 (grid%id, 0)
160      CALL nl_set_io_form_auxinput7 (grid%id, 0)
161      CALL nl_set_io_form_auxinput8 (grid%id, 0)
162#endif
163
164      ! set diffusion to zero for backward integration
165
166#if (EM_CORE == 1)
167      CALL nl_set_km_opt( grid%id, grid%km_opt_dfi)
168      CALL nl_set_moist_adv_dfi_opt( grid%id, grid%moist_adv_dfi_opt)
169      IF ( grid%moist_adv_opt == 2 ) THEN
170         CALL nl_set_moist_adv_opt( grid%id, 0)
171      ENDIF
172#endif
173
174#if (NMM_CORE == 1)
175
176!
177! CHANGE (SIGN ONLY OF) IMPORTANT TIME CONSTANTS
178!
179      CALL nl_get_time_step( grid%id, grid%time_step )
180      if (grid%time_step .lt. 0) then
181!       DT   =-DT
182
183        write(mess,*) 'changing signs for backward integration'
184        call wrf_message(mess)
185        grid%CPGFV = -grid%CPGFV
186        grid%EN    = -grid%EN
187        grid%ENT   = -grid%ENT
188        grid%F4D   = -grid%F4D
189        grid%F4Q   = -grid%F4Q
190        grid%EF4T  = -grid%EF4T
191 
192        grid%EM(:) = -grid%EM(:)
193        grid%EMT(:) = -grid%EMT(:)
194        grid%F4Q2(:) = -grid%F4Q2(:)
195 
196        grid%WPDAR(:,:)= -grid%WPDAR(:,:)
197        grid%CPGFU(:,:)= -grid%CPGFU(:,:)
198        grid%CURV(:,:)= -grid%CURV(:,:)
199        grid%FCP(:,:)= -grid%FCP(:,:)
200        grid%FAD(:,:)= -grid%FAD(:,:)
201        grid%F(:,:)= -grid%F(:,:)
202      endif
203#endif
204
205      grid%start_subtime = domain_get_start_time ( grid )
206      grid%stop_subtime = domain_get_stop_time ( grid )
207
208      CALL WRFU_ClockSet(grid%domain_clock, currTime=grid%start_subtime, rc=rc)
209
210      CALL dfi_save_arrays ( grid )
211      CALL dfi_clear_accumulation( grid )
212      CALL optfil_driver(grid)
213
214      !tgs need to call start_domain here to reset bc initialization for negative dt
215      CALL start_domain ( grid , .TRUE. )
216
217   END SUBROUTINE dfi_bck_init
218
219
220   SUBROUTINE dfi_fwd_init ( grid )
221
222      USE module_domain, ONLY : domain, head_grid, domain_get_stop_time, domain_get_start_time
223      USE module_utility
224      USE module_state_description
225
226      IMPLICIT NONE
227
228      TYPE (domain) , POINTER                 :: grid
229      INTEGER rc
230      CHARACTER*80 mess
231
232      INTERFACE
233         SUBROUTINE Setup_Timekeeping(grid)
234            USE module_domain, ONLY : domain
235            TYPE (domain), POINTER :: grid
236         END SUBROUTINE Setup_Timekeeping
237
238         SUBROUTINE dfi_save_arrays(grid)
239            USE module_domain, ONLY : domain
240            TYPE (domain), POINTER :: grid
241         END SUBROUTINE dfi_save_arrays
242
243         SUBROUTINE dfi_clear_accumulation(grid)
244            USE module_domain, ONLY : domain
245            TYPE (domain), POINTER :: grid
246         END SUBROUTINE dfi_clear_accumulation
247
248         SUBROUTINE optfil_driver(grid)
249            USE module_domain, ONLY : domain
250            TYPE (domain), POINTER :: grid
251         END SUBROUTINE optfil_driver
252
253         SUBROUTINE start_domain(grid, allowed_to_read)
254            USE module_domain, ONLY : domain
255            TYPE (domain)          :: grid
256            LOGICAL, INTENT(IN)    :: allowed_to_read
257         END SUBROUTINE start_domain
258      END INTERFACE
259
260      grid%dfi_stage = DFI_FWD
261
262      ! for Setup_Timekeeping to use when setting the clock
263
264      IF ( grid%time_step_dfi .gt. 0 ) THEN
265        CALL nl_set_time_step ( grid%id, grid%time_step_dfi )
266      ELSE
267
268      CALL nl_get_time_step( grid%id, grid%time_step )
269        CALL nl_get_time_step_fract_num( grid%id, grid%time_step_fract_num )
270
271      grid%time_step = abs(grid%time_step)
272      CALL nl_set_time_step( grid%id, grid%time_step )
273
274        grid%time_step_fract_num = abs(grid%time_step_fract_num)
275        CALL nl_set_time_step_fract_num( grid%id, grid%time_step_fract_num )
276
277      ENDIF
278
279      grid%itimestep=0
280      grid%xtime=0.
281
282      ! reset physics options to normal
283      CALL nl_set_mp_physics( grid%id, grid%mp_physics)
284      CALL nl_set_ra_lw_physics( grid%id, grid%ra_lw_physics)
285      CALL nl_set_ra_sw_physics( grid%id, grid%ra_sw_physics)
286      CALL nl_set_sf_surface_physics( grid%id, grid%sf_surface_physics)
287      CALL nl_set_sf_sfclay_physics( grid%id, grid%sf_sfclay_physics)
288      CALL nl_set_sf_urban_physics( grid%id, grid%sf_urban_physics)
289      CALL nl_set_bl_pbl_physics( grid%id, grid%bl_pbl_physics)
290      CALL nl_set_cu_physics( grid%id, grid%cu_physics)
291      CALL nl_set_damp_opt( grid%id, grid%damp_opt)
292      CALL nl_set_sst_update( grid%id, 0)
293      CALL nl_set_fractional_seaice( grid%id, grid%fractional_seaice)
294      CALL nl_set_gwd_opt( grid%id, grid%gwd_opt)
295      CALL nl_set_feedback( grid%id, 0 )
296#if (EM_CORE == 1)
297      CALL nl_set_diff_6th_opt( grid%id, grid%diff_6th_opt)
298      CALL nl_set_use_adaptive_time_step( grid%id, .false. )
299      ! set bc
300      CALL nl_set_constant_bc(grid%id, grid%constant_bc)
301#endif
302
303#if (NMM_CORE == 1)
304!
305! CHANGE (SIGN ONLY OF) IMPORTANT TIME CONSTANTS
306!
307!mptest      CALL nl_get_time_step( grid%id, grid%time_step )
308
309
310!!! here need to key off something else being the "wrong" sign
311      if (grid%cpgfv .gt. 0) then
312
313        write(mess,*) 'changing signs for forward integration'
314        call wrf_message(mess)
315        grid%CPGFV = -grid%CPGFV
316        grid%EN    = -grid%EN
317        grid%ENT   = -grid%ENT
318        grid%F4D   = -grid%F4D
319        grid%F4Q   = -grid%F4Q
320        grid%EF4T  = -grid%EF4T
321 
322        grid%EM(:) = -grid%EM(:)
323        grid%EMT(:) = -grid%EMT(:)
324        grid%F4Q2(:) = -grid%F4Q2(:)
325 
326        grid%WPDAR(:,:)= -grid%WPDAR(:,:)
327        grid%CPGFU(:,:)= -grid%CPGFU(:,:)
328        grid%CURV(:,:)= -grid%CURV(:,:)
329        grid%FCP(:,:)= -grid%FCP(:,:)
330        grid%FAD(:,:)= -grid%FAD(:,:)
331        grid%F(:,:)= -grid%F(:,:)
332      endif
333#endif
334
335
336!#ifdef WRF_CHEM
337!      ! reset chem option to normal
338!      CALL nl_set_chem_opt( grid%id, grid%chem_opt)
339!      CALL nl_set_aer_ra_feedback (grid%id, grid%aer_ra_feedback)
340!#endif
341
342#if (EM_CORE == 1)
343      ! reset km_opt to norlmal
344      CALL nl_set_km_opt( grid%id, grid%km_opt)
345      CALL nl_set_moist_adv_opt( grid%id, grid%moist_adv_opt)
346#endif
347
348
349      CALL Setup_Timekeeping (grid)
350      grid%start_subtime = domain_get_start_time ( head_grid )
351      grid%stop_subtime = domain_get_stop_time ( head_grid )
352
353      CALL WRFU_ClockSet(grid%domain_clock, currTime=grid%start_subtime, rc=rc)
354
355      IF ( grid%dfi_opt .EQ. DFI_DFL ) THEN
356         CALL dfi_save_arrays ( grid )
357      END IF
358      CALL dfi_clear_accumulation( grid )
359      CALL optfil_driver(grid)
360
361      !tgs need to call it here to reset bc initialization for positive time_step
362      CALL start_domain ( grid , .TRUE. )
363
364   END SUBROUTINE dfi_fwd_init
365
366   SUBROUTINE dfi_fst_init ( grid )
367
368      USE module_domain, ONLY : domain, domain_get_stop_time, domain_get_start_time
369      USE module_state_description
370
371      IMPLICIT NONE
372
373      TYPE (domain) , POINTER :: grid
374      CHARACTER (LEN=80)      :: wrf_error_message
375
376      INTERFACE
377         SUBROUTINE Setup_Timekeeping(grid)
378            USE module_domain, ONLY : domain
379            TYPE (domain), POINTER :: grid
380         END SUBROUTINE Setup_Timekeeping
381
382         SUBROUTINE dfi_save_arrays(grid)
383            USE module_domain, ONLY : domain
384            TYPE (domain), POINTER :: grid
385         END SUBROUTINE dfi_save_arrays
386
387         SUBROUTINE dfi_clear_accumulation(grid)
388            USE module_domain, ONLY : domain
389            TYPE (domain), POINTER :: grid
390         END SUBROUTINE dfi_clear_accumulation
391
392         SUBROUTINE optfil_driver(grid)
393            USE module_domain, ONLY : domain
394            TYPE (domain), POINTER :: grid
395         END SUBROUTINE optfil_driver
396
397         SUBROUTINE start_domain(grid, allowed_to_read)
398            USE module_domain, ONLY : domain
399            TYPE (domain)          :: grid
400            LOGICAL, INTENT(IN)    :: allowed_to_read
401         END SUBROUTINE start_domain
402      END INTERFACE
403
404      grid%dfi_stage = DFI_FST
405
406     ! reset time_step to normal and adaptive_time_step
407      CALL nl_set_time_step( grid%id, grid%time_step )
408
409      grid%itimestep=0
410      grid%xtime=0.         ! BUG: This will probably not work for all DFI options
411! only use adaptive time stepping for forecast
412#if (EM_CORE == 1)
413      if (grid%id == 1) then
414         CALL nl_set_use_adaptive_time_step( 1, grid%use_adaptive_time_step )
415      endif
416      CALL nl_set_sst_update( grid%id, grid%sst_update)
417      ! reset to normal bc
418      CALL nl_set_constant_bc(grid%id, .false.)
419#endif
420      CALL nl_set_feedback( grid%id, grid%feedback )
421
422#ifdef WRF_CHEM
423      ! reset chem option to normal
424      CALL nl_set_chem_opt( grid%id, grid%chem_opt)
425      CALL nl_set_aer_ra_feedback (grid%id, grid%aer_ra_feedback)
426      CALL nl_set_io_form_auxinput5 (grid%id, grid%io_form_auxinput5)
427      CALL nl_set_io_form_auxinput7 (grid%id, grid%io_form_auxinput7)
428      CALL nl_set_io_form_auxinput8 (grid%id, grid%io_form_auxinput8)
429#endif
430
431
432      CALL Setup_Timekeeping (grid)
433      grid%start_subtime = domain_get_start_time ( grid )
434      grid%stop_subtime = domain_get_stop_time ( grid )
435
436      CALL start_domain ( grid , .TRUE. )
437
438   END SUBROUTINE dfi_fst_init
439
440
441   SUBROUTINE dfi_write_initialized_state( grid )
442
443      ! Driver layer
444      USE module_domain, ONLY : domain, head_grid
445      USE module_io_domain
446      USE module_configure, ONLY : grid_config_rec_type, model_config_rec
447
448      IMPLICIT NONE
449
450      TYPE (domain) , POINTER :: grid
451      INTEGER             :: fid, ierr
452      CHARACTER (LEN=80)  :: wrf_error_message
453      CHARACTER (LEN=80)  :: rstname
454      CHARACTER (LEN=132) :: message
455
456      TYPE (grid_config_rec_type) :: config_flags
457
458      CALL model_to_grid_config_rec ( grid%id , model_config_rec , config_flags )
459
460      WRITE (wrf_err_message,'(A,I4)') 'Writing out initialized model state'
461      CALL wrf_message(TRIM(wrf_err_message))
462
463      WRITE (rstname,'(A,I2.2)')'wrfinput_initialized_d',grid%id
464      CALL open_w_dataset ( fid, TRIM(rstname), grid, config_flags, output_input, "DATASET=INPUT", ierr )
465      IF ( ierr .NE. 0 ) THEN
466         WRITE( message , '("program wrf: error opening ",A," for writing")') TRIM(rstname)
467         CALL WRF_ERROR_FATAL ( message )
468      END IF
469      CALL output_input ( fid,   grid, config_flags, ierr )
470      CALL close_dataset ( fid, config_flags, "DATASET=INPUT" )
471
472   END SUBROUTINE dfi_write_initialized_state
473
474!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
475! DFI array reset group of functions
476!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
477
478   SUBROUTINE wrf_dfi_array_reset ( )
479
480      USE module_domain, ONLY : domain, head_grid, set_current_grid_ptr
481
482      IMPLICIT NONE
483
484      INTERFACE
485         RECURSIVE SUBROUTINE dfi_array_reset_recurse(grid)
486            USE module_domain, ONLY : domain
487            TYPE (domain), POINTER :: grid
488         END SUBROUTINE dfi_array_reset_recurse
489      END INTERFACE
490
491      ! Copy filtered arrays back into state arrays in grid structure, and
492      !   restore original land surface fields
493
494      CALL dfi_array_reset_recurse(head_grid)
495
496      CALL set_current_grid_ptr( head_grid )
497
498   END SUBROUTINE wrf_dfi_array_reset
499
500   SUBROUTINE dfi_array_reset( grid )
501
502      USE module_domain, ONLY : domain
503!      USE module_configure
504!      USE module_driver_constants
505!      USE module_machine
506!      USE module_dm
507      USE module_model_constants
508      USE module_state_description
509
510      IMPLICIT NONE
511
512      INTEGER :: its, ite, jts, jte, kts, kte, &
513                 i, j, k
514
515      !  Input data.
516      TYPE(domain) , POINTER          :: grid
517
518      ! local
519!      real p1000mb,eps,svp1,svp2,svp3,svpt0
520      real eps
521!      parameter (p1000mb = 1.e+05, eps=0.622,svp1=0.6112,svp3=29.65,svpt0=273.15)
522      parameter (eps=0.622)
523      REAL es,qs,pol,tx,temp,pres,rslf             
524      CHARACTER*80 mess
525
526      IF ( grid%dfi_opt .EQ. DFI_NODFI ) RETURN
527
528
529      ! Set dynamic variables
530      ! divide by total DFI coefficient
531
532#if (EM_CORE == 1)
533      grid%mu_2(:,:)    = grid%dfi_mu(:,:)      / grid%hcoeff_tot
534      grid%u_2(:,:,:)   = grid%dfi_u(:,:,:)     / grid%hcoeff_tot
535      grid%v_2(:,:,:)   = grid%dfi_v(:,:,:)     / grid%hcoeff_tot
536      grid%w_2(:,:,:)   = grid%dfi_w(:,:,:)     / grid%hcoeff_tot
537      grid%ww(:,:,:)    = grid%dfi_ww(:,:,:)    / grid%hcoeff_tot
538      grid%t_2(:,:,:)   = grid%dfi_t(:,:,:)     / grid%hcoeff_tot
539      grid%phb(:,:,:)   = grid%dfi_phb(:,:,:)   / grid%hcoeff_tot
540      grid%ph0(:,:,:)   = grid%dfi_ph0(:,:,:)   / grid%hcoeff_tot
541      grid%php(:,:,:)   = grid%dfi_php(:,:,:)   / grid%hcoeff_tot
542      grid%p(:,:,:)     = grid%dfi_p(:,:,:)     / grid%hcoeff_tot
543      grid%ph_2(:,:,:)  = grid%dfi_ph(:,:,:)    / grid%hcoeff_tot
544      grid%tke_2(:,:,:) = grid%dfi_tke(:,:,:)   / grid%hcoeff_tot
545      grid%al(:,:,:)    = grid%dfi_al(:,:,:)    / grid%hcoeff_tot
546      grid%alt(:,:,:)   = grid%dfi_alt(:,:,:)   / grid%hcoeff_tot
547      grid%pb(:,:,:)    = grid%dfi_pb(:,:,:)    / grid%hcoeff_tot
548#if ( WRF_DFI_RADAR == 1 )
549    IF ( grid%dfi_radar .EQ. 0 ) then   ! tgs no radar assimilation
550      grid%moist(:,:,:,:)  = max(0.,grid%dfi_moist(:,:,:,:)  / grid%hcoeff_tot)
551    ELSE
552      grid%moist(:,:,:,P_QV)  = max(0.,grid%dfi_moist(:,:,:,P_QV)  / grid%hcoeff_tot)
553    ENDIF
554#else
555      grid%moist(:,:,:,:)  = max(0.,grid%dfi_moist(:,:,:,:)  / grid%hcoeff_tot)
556#endif
557      grid%scalar(:,:,:,:) = max(0.,grid%dfi_scalar(:,:,:,:) / grid%hcoeff_tot)
558
559      ! restore initial fields
560      grid%SNOW  (:,:) = grid%dfi_SNOW  (:,:)
561      grid%SNOWH (:,:) = grid%dfi_SNOWH (:,:)
562      grid%SNOWC (:,:) = grid%dfi_SNOWC (:,:)
563      grid%CANWAT(:,:) = grid%dfi_CANWAT(:,:)
564      grid%TSK   (:,:) = grid%dfi_TSK   (:,:)
565
566      grid%TSLB  (:,:,:)       = grid%dfi_TSLB   (:,:,:)
567      grid%SMOIS (:,:,:)       = grid%dfi_SMOIS  (:,:,:)
568      IF ( grid%sf_surface_physics .EQ. 3 ) then
569         grid%QVG   (:,:) = grid%dfi_QVG   (:,:)
570         grid%TSNAV (:,:) = grid%dfi_TSNAV (:,:) 
571         grid%SOILT1(:,:) = grid%dfi_SOILT1(:,:)   
572         grid%SMFR3D(:,:,:)       = grid%dfi_SMFR3D (:,:,:)
573         grid%KEEPFR3DFLAG(:,:,:) = grid%dfi_KEEPFR3DFLAG(:,:,:)
574      ENDIF
575
576      ! restore analized hydrometeor fileds
577#if ( WRF_DFI_RADAR == 1 )
578    IF ( grid%dfi_radar .EQ. 1 ) then
579!      grid%moist(:,:,:,:)      = grid%dfi_moist(:,:,:,:)    !tgs
580      grid%moist(:,:,:,P_QC)      = grid%dfi_moist(:,:,:,P_QC)    !tgs
581      grid%moist(:,:,:,P_QR)      = grid%dfi_moist(:,:,:,P_QR)    !tgs
582      grid%moist(:,:,:,P_QI)      = grid%dfi_moist(:,:,:,P_QI)    !tgs
583      grid%moist(:,:,:,P_QS)      = grid%dfi_moist(:,:,:,P_QS)    !tgs
584      grid%moist(:,:,:,P_QG)      = grid%dfi_moist(:,:,:,P_QG)    !tgs
585
586       if(grid%dfi_stage .EQ. DFI_FWD) then
587!tgs change QV to restore initial RH field after the diabatic DFI
588            its = grid%sp31 ; ite = grid%ep31 ; 
589            kts = grid%sp32 ; kte = grid%ep32 ;
590            jts = grid%sp33 ; jte = grid%ep33 ;
591   DO j=jts,jte
592      DO i=its,ite
593         do k = kts , kte
594          temp = (grid%t_2(i,k,j)+t0)*( (grid%p(i,k,j)+grid%pb(i,k,j))/p1000mb )&
595                     ** (r_d / Cp)
596          pres = grid%p(i,k,j)+grid%pb(i,k,j)
597!tgs rslf - function to compute qs from Thompson microphysics
598          qs = rslf(pres, temp)
599
600!      if(i.eq. 178 .and. j.eq. 148 .and. k.eq.11) then
601!       print *,'temp,pres,qs-thomp',temp,pres,qs
602!      endif
603
604      IF(grid%moist(i,k,j,P_QC) .GT. 1.e-6 .or.                    &
605         grid%moist(i,k,j,P_QI) .GT. 1.e-6) THEN
606         grid%moist (i,k,j,P_QV) = MAX(0.,grid%dfi_rh(i,k,j)*QS)
607      ENDIF
608
609!      if(i.eq. 178 .and. j.eq. 148 .and. k.eq.11) then
610!       print *,'temp,pres,qs,grid%moist (i,k,j,P_QV)',temp,pres,qs,  &
611!                grid%moist(i,k,j,P_QV)
612!      endif
613         enddo
614      ENDDO
615   ENDDO
616       endif
617
618    ENDIF
619#endif
620#endif
621
622#if (NMM_CORE == 1)
623        write(mess,*) ' divide by grid%hcoeff_tot: ', grid%hcoeff_tot
624        call wrf_message(mess)
625        if (grid%hcoeff_tot .lt. 0.0001) then
626        call wrf_error_fatal("bad grid%hcoeff_tot")
627        endif
628       grid%pd(:,:)       = grid%dfi_pd(:,:)  / grid%hcoeff_tot
629       grid%pint(:,:,:)      = grid%dfi_pint(:,:,:) / grid%hcoeff_tot
630!       grid%dwdt(:,:,:)      = grid%dfi_dwdt(:,:,:) / grid%hcoeff_tot
631       grid%t(:,:,:)      = grid%dfi_t(:,:,:) / grid%hcoeff_tot
632       grid%q(:,:,:)      = grid%dfi_q(:,:,:) / grid%hcoeff_tot
633       grid%q2(:,:,:)     = grid%dfi_q2(:,:,:) / grid%hcoeff_tot
634       grid%cwm(:,:,:)    = grid%dfi_cwm(:,:,:) / grid%hcoeff_tot
635       grid%u(:,:,:)      = grid%dfi_u(:,:,:) / grid%hcoeff_tot
636       grid%v(:,:,:)      = grid%dfi_v(:,:,:) / grid%hcoeff_tot
637      grid%moist(:,:,:,:)  = grid%dfi_moist(:,:,:,:)  / grid%hcoeff_tot
638      grid%scalar(:,:,:,:) = grid%dfi_scalar(:,:,:,:) / grid%hcoeff_tot
639
640      ! restore initial fields
641      grid%SNOW(:,:)   = grid%dfi_SNOW(:,:)
642      grid%SNOWH(:,:)  = grid%dfi_SNOWH(:,:)
643!      grid%SNOWC(:,:)  = grid%dfi_SNOWC(:,:)
644      grid%CANWAT(:,:) = grid%dfi_CANWAT(:,:)
645      grid%NMM_TSK(:,:)    = grid%dfi_NMM_TSK(:,:)
646      ! save soil fields
647      grid%STC(:,:,:)         = grid%dfi_STC(:,:,:)
648      grid%SMC(:,:,:)        = grid%dfi_SMC(:,:,:)
649      grid%SH2O(:,:,:)       = grid%dfi_SH2O(:,:,:)
650#endif
651
652
653   END SUBROUTINE dfi_array_reset
654
655   SUBROUTINE optfil_driver( grid )
656
657      USE module_domain, ONLY : domain
658      USE module_utility
659!      USE module_wrf_error
660!      USE module_timing
661!      USE module_date_time
662!      USE module_configure
663      USE module_state_description
664      USE module_model_constants
665
666      IMPLICIT NONE
667
668      TYPE (domain) , POINTER                 :: grid
669
670      ! Local variables
671      integer :: nstep2, nstepmax, rundfi, i, rc,hr,min,sec
672      integer :: yr,jday
673      real :: timestep, tauc
674      TYPE(WRFU_TimeInterval) :: run_interval
675      CHARACTER*80 mess
676
677      timestep=abs(grid%dt)
678      run_interval = grid%stop_subtime - grid%start_subtime
679      CALL WRFU_TimeGet(grid%start_subtime, YY=yr, dayofYear=jday, H=hr, M=min, S=sec, rc=rc)
680      CALL WRFU_TimeGet(grid%stop_subtime, YY=yr, dayofYear=jday, H=hr, M=min, S=sec, rc=rc)
681
682      CALL WRFU_TimeIntervalGet( run_interval, S=rundfi, rc=rc )
683      rundfi = abs(rundfi)
684
685      nstep2= ceiling((1.0 + real(rundfi)/timestep) / 2.0)
686
687      ! nstep2 is equal to a half of timesteps per initialization period,
688      ! should not exceed nstepmax
689
690      tauc = real(grid%dfi_cutoff_seconds)
691
692      ! Get DFI coefficient
693      grid%hcoeff(:) = 0.0
694      IF ( grid%dfi_nfilter < 0 .OR. grid%dfi_nfilter > 8 ) THEN
695write(mess,*) 'Invalid filter specified in namelist.'
696call wrf_message(mess)
697      ELSE
698         call dfcoef(nstep2-1, grid%dt, tauc, grid%dfi_nfilter, grid%hcoeff)
699      END IF
700
701      IF ( MOD(int(1.0 + real(rundfi)/timestep),2) /= 0 ) THEN
702         DO i=1,nstep2-1
703            grid%hcoeff(2*nstep2-i) = grid%hcoeff(i)
704         END DO
705      ELSE
706         DO i=1,nstep2
707            grid%hcoeff(2*nstep2-i+1) = grid%hcoeff(i)
708         END DO
709      END IF
710
711   END SUBROUTINE optfil_driver
712
713
714   SUBROUTINE dfi_clear_accumulation( grid )
715
716      USE module_domain, ONLY : domain
717!      USE module_configure
718!      USE module_driver_constants
719!      USE module_machine
720!      USE module_dm
721!      USE module_model_constants
722      USE module_state_description
723
724      IMPLICIT NONE
725
726      !  Input data.
727      TYPE(domain) , POINTER          :: grid
728
729#if (EM_CORE == 1)
730      grid%dfi_mu(:,:)       = 0.
731      grid%dfi_u(:,:,:)      = 0.
732      grid%dfi_v(:,:,:)      = 0.
733      grid%dfi_w(:,:,:)      = 0.
734      grid%dfi_ww(:,:,:)     = 0.
735      grid%dfi_t(:,:,:)      = 0.
736      grid%dfi_phb(:,:,:)    = 0.
737      grid%dfi_ph0(:,:,:)    = 0.
738      grid%dfi_php(:,:,:)    = 0.
739      grid%dfi_p(:,:,:)      = 0.
740      grid%dfi_ph(:,:,:)     = 0.
741      grid%dfi_tke(:,:,:)    = 0.
742      grid%dfi_al(:,:,:)     = 0.
743      grid%dfi_alt(:,:,:)    = 0.
744      grid%dfi_pb(:,:,:)     = 0.
745#if ( WRF_DFI_RADAR == 1 )
746    IF ( grid%dfi_radar .EQ. 0 ) then 
747      grid%dfi_moist(:,:,:,:)  = 0.
748    ELSE
749      grid%dfi_moist(:,:,:,P_QV) = 0.
750    ENDIF
751#else
752      grid%dfi_moist(:,:,:,:)  = 0.
753#endif
754      grid%dfi_scalar(:,:,:,:) = 0.
755#endif
756
757#if (NMM_CORE == 1)
758       grid%dfi_pd(:,:)    = 0.
759       grid%dfi_pint(:,:,:)   = 0.
760       grid%dfi_dwdt(:,:,:)   = 0.
761       grid%dfi_t(:,:,:)   = 0.
762       grid%dfi_q(:,:,:)   = 0.
763       grid%dfi_q2(:,:,:)  = 0.
764       grid%dfi_cwm(:,:,:) = 0.
765       grid%dfi_u(:,:,:)   = 0.
766       grid%dfi_v(:,:,:)   = 0.
767      grid%dfi_moist(:,:,:,:)  = 0.
768      grid%dfi_scalar(:,:,:,:) = 0.
769#endif
770
771      grid%hcoeff_tot  = 0.0
772
773   END SUBROUTINE dfi_clear_accumulation
774
775
776   SUBROUTINE dfi_save_arrays( grid )
777
778      USE module_domain, ONLY : domain
779!      USE module_configure
780!      USE module_driver_constants
781!      USE module_machine
782!      USE module_dm
783      USE module_model_constants
784      USE module_state_description
785
786      IMPLICIT NONE
787
788      INTEGER :: its, ite, jts, jte, kts, kte, &
789                 i, j, k
790
791      !  Input data.
792      TYPE(domain) , POINTER          :: grid
793      ! local
794
795      REAL es,qs,pol,tx,temp,pres,rslf
796
797#if (EM_CORE == 1)
798      ! save surface 2-D fields
799      grid%dfi_SNOW(:,:)   = grid%SNOW(:,:)
800      grid%dfi_SNOWH(:,:)  = grid%SNOWH(:,:)
801      grid%dfi_SNOWC(:,:)  = grid%SNOWC(:,:)
802      grid%dfi_CANWAT(:,:) = grid%CANWAT(:,:)
803      grid%dfi_TSK(:,:)    = grid%TSK(:,:)
804
805      ! save soil fields
806      grid%dfi_TSLB(:,:,:)         = grid%TSLB(:,:,:)
807      grid%dfi_SMOIS(:,:,:)        = grid%SMOIS(:,:,:)
808      ! RUC LSM only, need conditional
809      IF ( grid%sf_surface_physics .EQ. 3 ) then
810         grid%dfi_QVG(:,:)            = grid%QVG(:,:)
811         grid%dfi_SOILT1(:,:)         = grid%SOILT1(:,:)
812         grid%dfi_TSNAV(:,:)          = grid%TSNAV(:,:)
813         grid%dfi_SMFR3D(:,:,:)       = grid%SMFR3D(:,:,:)
814         grid%dfi_KEEPFR3DFLAG(:,:,:) = grid%KEEPFR3DFLAG(:,:,:)
815      ENDIF
816#endif
817
818#if (NMM_CORE == 1)
819      ! save surface 2-D fields
820      grid%dfi_SNOW(:,:)   = grid%SNOW(:,:)
821      grid%dfi_SNOWH(:,:)  = grid%SNOWH(:,:)
822!      grid%dfi_SNOWC(:,:)  = grid%SNOWC(:,:)
823      grid%dfi_CANWAT(:,:) = grid%CANWAT(:,:)
824      grid%dfi_NMM_TSK(:,:)    = grid%NMM_TSK(:,:)
825      ! save soil fields
826      grid%dfi_STC(:,:,:)         = grid%STC(:,:,:)
827      grid%dfi_SMC(:,:,:)        = grid%SMC(:,:,:)
828      grid%dfi_SH2O(:,:,:)       = grid%SH2O(:,:,:)
829#endif
830
831
832      ! save hydrometeor fields
833#if (EM_CORE == 1)
834#if ( WRF_DFI_RADAR == 1 )
835    IF ( grid%dfi_radar .EQ. 1 ) then    !tgs
836!      grid%dfi_moist(:,:,:,:)  =   grid%moist(:,:,:,:)
837      grid%dfi_moist(:,:,:,P_QC)  =   grid%moist(:,:,:,P_QC)
838      grid%dfi_moist(:,:,:,P_QR)  =   grid%moist(:,:,:,P_QR)
839      grid%dfi_moist(:,:,:,P_QI)  =   grid%moist(:,:,:,P_QI)
840      grid%dfi_moist(:,:,:,P_QS)  =   grid%moist(:,:,:,P_QS)
841      grid%dfi_moist(:,:,:,P_QG)  =   grid%moist(:,:,:,P_QG)
842
843       if(grid%dfi_stage .EQ. DFI_BCK) then
844! compute initial RH field to be reintroduced after the diabatic DFI
845            its = grid%sp31 ; ite = grid%ep31 ; 
846            kts = grid%sp32 ; kte = grid%ep32 ;
847            jts = grid%sp33 ; jte = grid%ep33 ;
848   DO j=jts,jte
849      DO i=its,ite
850         do k = kts , kte
851          temp = (grid%t_2(i,k,j)+t0)*( (grid%p(i,k,j)+grid%pb(i,k,j))/p1000mb )&
852                     ** (r_d / Cp)
853          pres = grid%p(i,k,j)+grid%pb(i,k,j)
854!tgs rslf - function to compute qs from Thompson microphysics
855          qs = rslf(pres, temp)
856          grid%dfi_rh (i,k,j) = MIN(1.,MAX(0.,grid%moist(i,k,j,P_QV)/qs))
857
858!tgs saturation check for points with water or ice clouds
859      IF ((grid%moist (i,k,j,P_QC) .GT. 1.e-6  .or.        &
860          grid%moist (i,k,j,P_QI) .GT. 1.e-6)  .and.       &
861          grid%dfi_rh (i,k,j) .lt. 1.) THEN
862               grid%dfi_rh (i,k,j)=1.
863      ENDIF
864         
865        end do
866      END DO
867    ENDDO
868       endif
869
870    ENDIF
871#endif
872#endif
873
874   END SUBROUTINE dfi_save_arrays
875
876
877   SUBROUTINE dfcoef (NSTEPS,DT,TAUC,NFILT,H)
878!
879!     calculate filter weights with selected window.
880!
881!       peter lynch and xiang-yu huang
882!
883!       ref: see hamming, r.w., 1989: digital filters,
884!                prentice-hall international. 3rd edition.
885!
886!       input:      nsteps  -  number of timesteps
887!                              forward or backward.
888!                   dt      -  time step in seconds.
889!                   tauc    -  cut-off period in seconds.
890!                   nfilt   -  indicator for selected filter.
891!
892!       output:     h       -  array(0:nsteps) with the
893!                              required filter weights
894!
895!------------------------------------------------------------
896 
897      implicit none
898
899      integer, intent(in)   :: nsteps, nfilt
900      real   , intent(in)   :: dt, tauc
901      real, intent(out)  :: h(1:nsteps+1)
902     
903      ! Local data
904
905      integer               :: n
906      real                  :: pi, omegac, x, window, deltat
907      real                  :: hh(0:nsteps)
908
909      pi=4*ATAN(1.)
910      deltat=ABS(dt)
911
912      ! windows are defined by a call and held in hh.
913
914      if ( nfilt .eq. -1) call debug    (nsteps,h)
915
916      IF ( NFILT .EQ. 0 ) CALL UNIFORM  (NSTEPS,HH)
917      IF ( NFILT .EQ. 1 ) CALL LANCZOS  (NSTEPS,HH)
918      IF ( NFILT .EQ. 2 ) CALL HAMMING  (NSTEPS,HH)
919      IF ( NFILT .EQ. 3 ) CALL BLACKMAN (NSTEPS,HH)
920      IF ( NFILT .EQ. 4 ) CALL KAISER   (NSTEPS,HH)
921      IF ( NFILT .EQ. 5 ) CALL POTTER2  (NSTEPS,HH)
922      IF ( NFILT .EQ. 6 ) CALL DOLPHWIN (NSTEPS,HH)
923
924      IF ( NFILT .LE. 6 ) THEN     ! sinc-windowed filters
925
926         ! calculate the cutoff frequency
927         OMEGAC = 2.*PI/TAUC
928
929         DO N=0,NSTEPS
930            WINDOW = HH(N)
931            IF ( N .EQ. 0 ) THEN
932              X = (OMEGAC*DELTAT/PI)
933            ELSE
934              X = SIN(N*OMEGAC*DELTAT)/(N*PI)
935            END IF
936            HH(N) = X*WINDOW
937         END DO
938
939         ! normalize the sums to be unity
940         CALL NORMLZ(HH,NSTEPS)
941
942         DO N=0,NSTEPS
943            H(N+1) = HH(NSTEPS-N)
944         END DO
945
946      ELSE IF ( NFILT .EQ. 7 ) THEN     ! dolph filter
947
948         CALL DOLPH(DT,TAUC,NSTEPS,H)
949
950      ELSE IF ( NFILT .EQ. 8 ) THEN     ! 2nd order, 2nd type quick start filter (RHO)
951
952         CALL RHOFIL(DT,TAUC,2,NSTEPS*2,2,H,NSTEPS)
953
954      END IF
955
956      RETURN
957
958   END SUBROUTINE dfcoef
959
960
961   SUBROUTINE NORMLZ(HH,NMAX)
962
963   ! normalize the sum of hh to be unity
964
965      implicit none
966 
967      integer, intent(in)                       :: nmax
968      real   , dimension(0:nmax), intent(out)   :: hh
969
970      ! local data
971      real     :: sumhh
972      integer  :: n
973
974      SUMHH = HH(0)
975      DO N=1,NMAX
976        SUMHH = SUMHH + 2*HH(N)
977      ENDDO
978      DO N=0,NMAX
979        HH(N)  = HH(N)/SUMHH
980      ENDDO
981
982      RETURN
983
984   END subroutine normlz
985
986
987   subroutine debug(nsteps, ww)
988
989      implicit none
990
991      integer, intent(in)                        :: nsteps
992      real   , dimension(0:nsteps), intent(out)  :: ww
993      integer :: n
994
995      do n=0,nsteps
996         ww(n)=0
997      end do
998
999      ww(int(nsteps/2))=1
1000
1001      return
1002
1003   end subroutine debug
1004
1005
1006   SUBROUTINE UNIFORM(NSTEPS,WW)
1007
1008   !  define uniform or rectangular window function.
1009
1010      implicit none
1011
1012      integer, intent(in)                        :: nsteps
1013      real   , dimension(0:nsteps), intent(out)  :: ww
1014       
1015      integer          :: n
1016
1017      DO N=0,NSTEPS
1018        WW(N) = 1.
1019      ENDDO
1020
1021      RETURN
1022
1023   END subroutine uniform
1024
1025
1026   SUBROUTINE LANCZOS(NSTEPS,WW)
1027
1028   ! define (genaralised) lanczos window function.
1029
1030      implicit none
1031
1032      integer,  parameter                      :: nmax = 1000
1033      integer,  intent(in)                     :: nsteps
1034      real   ,  dimension(0:nmax), intent(out) :: ww
1035      integer  ::  n
1036      real     :: power, pi, w
1037
1038      ! (for the usual lanczos window, power = 1 )
1039      POWER = 1
1040
1041      PI=4*ATAN(1.)
1042      DO N=0,NSTEPS
1043         IF ( N .EQ. 0 ) THEN
1044            W = 1.0
1045         ELSE
1046            W = SIN(N*PI/(NSTEPS+1)) / ( N*PI/(NSTEPS+1))
1047         ENDIF
1048         WW(N) = W**POWER
1049      ENDDO
1050
1051      RETURN
1052
1053   END SUBROUTINE lanczos
1054
1055
1056   SUBROUTINE HAMMING(NSTEPS,WW)
1057
1058   ! define (genaralised) hamming window function.
1059
1060      implicit none
1061
1062      integer, intent(in)           :: nsteps
1063      real, dimension(0:nsteps)    :: ww
1064      integer   ::   n
1065      real      :: alpha, pi, w
1066
1067      ! (for the usual hamming window, alpha=0.54,
1068      !      for the hann window, alpha=0.50).
1069      ALPHA=0.54
1070
1071      PI=4*ATAN(1.)
1072      DO N=0,NSTEPS
1073         IF ( N .EQ. 0 ) THEN
1074            W = 1.0
1075         ELSE
1076            W = ALPHA + (1-ALPHA)*COS(N*PI/(NSTEPS))
1077         ENDIF
1078         WW(N) = W
1079      ENDDO
1080
1081      RETURN
1082
1083   END SUBROUTINE hamming
1084
1085
1086   SUBROUTINE BLACKMAN(NSTEPS,WW)
1087
1088   ! define blackman window function.
1089
1090      implicit none
1091
1092      integer, intent(in)           :: nsteps
1093      real, dimension(0:nsteps)    :: ww
1094      integer  :: n
1095
1096      real :: pi, w
1097
1098      PI=4*ATAN(1.)
1099      DO N=0,NSTEPS
1100         IF ( N .EQ. 0 ) THEN
1101            W = 1.0
1102         ELSE
1103            W = 0.42 + 0.50*COS(  N*PI/(NSTEPS))   &
1104                     + 0.08*COS(2*N*PI/(NSTEPS))
1105         ENDIF
1106         WW(N) = W
1107      ENDDO
1108
1109      RETURN
1110
1111   END SUBROUTINE blackman
1112
1113
1114   SUBROUTINE KAISER(NSTEPS,WW)
1115
1116   ! define kaiser window function.
1117
1118      implicit none
1119
1120      real, external :: bessi0
1121
1122      integer, intent(in)           :: nsteps
1123      real, dimension(0:nsteps)    :: ww
1124      integer   :: n
1125      real      :: alpha, xi0a, xn, as
1126
1127      ALPHA = 1
1128
1129      XI0A =  BESSI0(ALPHA)
1130      DO N=0,NSTEPS
1131         XN = N
1132         AS = ALPHA*SQRT(1.-(XN/NSTEPS)**2)
1133         WW(N) = BESSI0(AS) / XI0A
1134      ENDDO
1135
1136      RETURN
1137
1138   END SUBROUTINE kaiser
1139
1140
1141   REAL FUNCTION BESSI0(X)
1142
1143   ! from numerical recipes (press, et al.)
1144
1145      implicit none
1146
1147      real(8)   :: Y
1148      real(8)   :: P1 = 1.0d0
1149      real(8)   :: P2 = 3.5156230D0
1150      real(8)   :: P3 = 3.0899424D0
1151      real(8)   :: P4 = 1.2067492D0
1152      real(8)   :: P5 = 0.2659732D0
1153      real(8)   :: P6 = 0.360768D-1
1154      real(8)   :: P7 = 0.45813D-2
1155
1156      real*8    :: Q1 = 0.39894228D0
1157      real*8    :: Q2 = 0.1328592D-1
1158      real*8    :: Q3 = 0.225319D-2
1159      real*8    :: Q4 = -0.157565D-2
1160      real*8    :: Q5 = 0.916281D-2
1161      real*8    :: Q6 = -0.2057706D-1
1162      real*8    :: Q7 = 0.2635537D-1
1163      real*8    :: Q8 = -0.1647633D-1
1164      real*8    :: Q9 = 0.392377D-2
1165
1166      real            :: x, ax
1167
1168
1169      IF (ABS(X).LT.3.75) THEN
1170        Y=(X/3.75)**2
1171        BESSI0=P1+Y*(P2+Y*(P3+Y*(P4+Y*(P5+Y*(P6+Y*P7)))))
1172      ELSE
1173        AX=ABS(X)
1174        Y=3.75/AX
1175        BESSI0=(EXP(AX)/SQRT(AX))*(Q1+Y*(Q2+Y*(Q3+Y*(Q4    &
1176           +Y*(Q5+Y*(Q6+Y*(Q7+Y*(Q8+Y*Q9))))))))
1177      ENDIF
1178      RETURN
1179
1180   END FUNCTION bessi0
1181
1182
1183   SUBROUTINE POTTER2(NSTEPS,WW)
1184
1185      ! define potter window function.
1186      ! modified to fall off over twice the range.
1187
1188      implicit none
1189
1190      integer, intent(in)                       :: nsteps
1191      real, dimension(0:nsteps),intent(out)     ::  ww
1192      integer  :: n
1193      real     :: ck, sum, arg
1194
1195      ! local data
1196      real, dimension(0:3)   :: d
1197      real                   :: pi
1198      integer                :: ip
1199
1200      d(0) = 0.35577019
1201      d(1) = 0.2436983
1202      d(2) = 0.07211497
1203      d(3) = 0.00630165
1204
1205      PI=4*ATAN(1.)
1206
1207      CK = 1.0
1208      DO N=0,NSTEPS
1209         IF (N.EQ.NSTEPS) CK = 0.5
1210         ARG = PI*FLOAT(N)/FLOAT(NSTEPS)
1211!min---        modification in next statement
1212         ARG = ARG/2.
1213!min---        end of modification
1214         SUM = D(0)
1215         DO IP=1,3
1216            SUM = SUM + 2.*D(IP)*COS(ARG*FLOAT(IP))
1217         END DO
1218         WW(N) = CK*SUM
1219      END DO
1220
1221      RETURN
1222
1223   END SUBROUTINE potter2
1224
1225
1226   SUBROUTINE dolphwin(m, window)
1227
1228!     calculation of dolph-chebyshev window or, for short,
1229!     dolph window, using the expression in the reference:
1230!
1231!     antoniou, andreas, 1993: digital filters: analysis,
1232!     design and applications. mcgraw-hill, inc., 689pp.
1233!
1234!     the dolph window is optimal in the following sense:
1235!     for a given main-lobe width, the stop-band attenuation
1236!     is minimal; for a given stop-band level, the main-lobe
1237!     width is minimal.
1238!
1239!     it is possible to specify either the ripple-ratio r
1240!     or the stop-band edge thetas.
1241
1242      IMPLICIT NONE
1243
1244      ! Arguments
1245      INTEGER, INTENT(IN)                  ::  m
1246      REAL, DIMENSION(0:M), INTENT(OUT)    ::  window
1247
1248      ! local data
1249      REAL, DIMENSION(0:2*M)               :: t
1250      REAL, DIMENSION(0:M)                 :: w, time
1251      REAL    :: pi, thetas, x0, term1, term2, rr, r, db, sum, arg
1252      INTEGER :: n, nm1, nt, i
1253
1254      PI = 4*ATAN(1.D0)
1255      THETAS = 2*PI/M
1256
1257      N = 2*M+1
1258      NM1 = N-1
1259      X0 = 1/COS(THETAS/2)
1260
1261      TERM1 = (X0 + SQRT(X0**2-1))**(FLOAT(N-1))
1262      TERM2 = (X0 - SQRT(X0**2-1))**(FLOAT(N-1))
1263      RR = 0.5*(TERM1+TERM2)
1264      R = 1/RR
1265      DB = 20*LOG10(R)
1266      WRITE(*,'(1X,''DOLPH: M,N='',2I8)')M,N
1267      WRITE(*,'(1X,''DOLPH: THETAS (STOP-BAND EDGE)='',F10.3)')THETAS
1268      WRITE(*,'(1X,''DOLPH: R,DB='',2F10.3)')R, DB
1269
1270      DO NT=0,M
1271        SUM = RR
1272        DO I=1,M
1273          ARG = X0*COS(I*PI/N)
1274          CALL CHEBY(T,NM1,ARG)
1275          TERM1 = T(NM1)
1276          TERM2 = COS(2*NT*PI*I/N)
1277          SUM = SUM + 2*TERM1*TERM2
1278        ENDDO
1279        W(NT) = SUM/N
1280        TIME(NT) = NT
1281      ENDDO
1282
1283!     fill up the array for return
1284      DO NT=0,M
1285        WINDOW(NT) = W(NT)
1286      ENDDO
1287
1288      RETURN
1289
1290   END SUBROUTINE dolphwin
1291
1292
1293   SUBROUTINE dolph(deltat, taus, m, window)
1294
1295!     calculation of dolph-chebyshev window or, for short,
1296!     dolph window, using the expression in the reference:
1297!
1298!     antoniou, andreas, 1993: digital filters: analysis,
1299!     design and applications. mcgraw-hill, inc., 689pp.
1300!
1301!     the dolph window is optimal in the following sense:
1302!     for a given main-lobe width, the stop-band attenuation
1303!     is minimal; for a given stop-band level, the main-lobe
1304!     width is minimal.
1305
1306      IMPLICIT NONE
1307
1308      ! Arguments
1309      INTEGER, INTENT(IN)                  ::  m
1310      REAL, DIMENSION(0:M), INTENT(OUT)    ::  window
1311      REAL, INTENT(IN)                     :: deltat, taus
1312
1313      ! local data
1314      integer, PARAMETER        :: NMAX = 5000
1315      REAL, dimension(0:NMAX)   :: t, w, time
1316      real, dimension(0:2*nmax) :: w2
1317      INTEGER                   :: NPRPE=0        ! no of pe
1318      CHARACTER*80              :: MES
1319
1320      real    :: pi, thetas, x0, term1, term2, rr, r,db, sum, arg, sumw
1321      integer :: n, nm1, i, nt
1322     
1323      PI = 4*ATAN(1.D0)
1324
1325      WRITE (mes,'(A,F8.2,A,F10.2)') 'In dolph, deltat = ',deltat,' taus = ',taus
1326      CALL wrf_message(TRIM(mes))
1327
1328      N = 2*M+1
1329      NM1 = N-1
1330
1331      THETAS = 2*PI*ABS(DELTAT/TAUS)
1332      X0 = 1/COS(THETAS/2)
1333      TERM1 = (X0 + SQRT(X0**2-1))**(FLOAT(N-1))
1334      TERM2 = (X0 - SQRT(X0**2-1))**(FLOAT(N-1))
1335      RR = 0.5*(TERM1+TERM2)
1336      R = 1/RR
1337      DB = 20*LOG10(R)
1338
1339      WRITE (mes,'(A,2I8)') 'In dolph: M,N = ', M,N
1340      CALL wrf_message(TRIM(mes))
1341      WRITE (mes,'(A,F10.3)') 'In dolph: THETAS (STOP-BAND EDGE) = ', thetas
1342      CALL wrf_message(TRIM(mes))
1343      WRITE (mes,'(A,2F10.3)') 'In dolph: R,DB = ', R,DB
1344      CALL wrf_message(TRIM(mes))
1345
1346      DO NT=0,M
1347         SUM = 1
1348         DO I=1,M
1349            ARG = X0*COS(I*PI/N)
1350            CALL CHEBY(T,NM1,ARG)
1351            TERM1 = T(NM1)
1352            TERM2 = COS(2*NT*PI*I/N)
1353            SUM = SUM + R*2*TERM1*TERM2
1354         ENDDO
1355         W(NT) = SUM/N
1356         TIME(NT) = NT
1357         WRITE (mes,'(A,F10.6,2x,E17.7)') 'In dolph: TIME, W = ', TIME(NT), W(NT)
1358         CALL wrf_message(TRIM(mes))
1359      ENDDO
1360!     fill in the negative-time values by symmetry.
1361      DO NT=0,M
1362         W2(M+NT) = W(NT)
1363         W2(M-NT) = W(NT)
1364      ENDDO
1365
1366!     fill up the array for return
1367      SUMW = 0.
1368      DO NT=0,2*M
1369         SUMW = SUMW + W2(NT)
1370      ENDDO
1371      WRITE (mes,'(A,F10.4)') 'In dolph: SUM OF WEIGHTS W2 = ', sumw
1372      CALL wrf_message(TRIM(mes))
1373
1374      DO NT=0,M
1375         WINDOW(NT) = W2(NT)
1376      ENDDO
1377
1378      RETURN
1379
1380   END SUBROUTINE dolph
1381
1382
1383   SUBROUTINE cheby(t, n, x)
1384
1385!     calculate all chebyshev polynomials up to order n
1386!     for the argument value x.
1387
1388!     reference: numerical recipes, page 184, recurrence
1389!         t_n(x) = 2xt_{n-1}(x) - t_{n-2}(x) ,  n>=2.
1390
1391      IMPLICIT NONE
1392
1393      ! Arguments
1394      INTEGER, INTENT(IN)  :: n
1395      REAL, INTENT(IN)     :: x
1396      REAL, DIMENSION(0:N) :: t
1397 
1398      integer  :: nn
1399
1400      T(0) = 1
1401      T(1) = X
1402      IF(N.LT.2) RETURN
1403      DO NN=2,N
1404         T(NN) = 2*X*T(NN-1) - T(NN-2)
1405      ENDDO
1406
1407      RETURN
1408
1409   END SUBROUTINE cheby
1410
1411
1412   SUBROUTINE rhofil(dt, tauc, norder, nstep, ictype, frow, nosize)
1413
1414!       RHO = recurssive high order.
1415!
1416!       This routine calculates and returns the
1417!       Last Row, FROW, of the FILTER matrix.
1418!
1419!       Input Parameters:
1420!              DT  :  Time Step in seconds
1421!            TAUC  :  Cut-off period (hours)
1422!          NORDER  :  Order of QS Filter
1423!           NSTEP  :  Number of step/Size of row.
1424!          ICTYPE  :  Initial Conditions
1425!          NOSIZE  :  Max. side of FROW.
1426!
1427!       Working Fields:
1428!           ACOEF  :  X-coefficients of filter
1429!           BCOEF  :  Y-coefficients of filter
1430!          FILTER  :  Filter Matrix.
1431!
1432!       Output Parameters:
1433!            FROW  : Last Row of Filter Matrix.
1434!
1435!       Note: Two types of initial conditions are permitted.
1436!          ICTYPE = 1 : Order increasing each row to NORDER.
1437!          ICTYPE = 2 : Order fixed at NORDER throughout.
1438!
1439!       DOUBLE PRECISION USED THROUGHOUT.
1440
1441      IMPLICIT DOUBLE PRECISION (A-H,O-Z)
1442
1443      DOUBLE PRECISION MUC
1444
1445!       N.B. Single Precision for List Parameters.
1446      REAL, intent(in)    ::  DT,TAUC
1447
1448!       Space for the last row of FILTER.
1449      integer, intent(in) ::  norder, nstep, ictype, nosize
1450      REAL   , dimension(0:nosize), intent(out)::  FROW
1451
1452!       Arrays for rho filter.
1453      integer, PARAMETER  :: NOMAX=100
1454      real   , dimension(0:NOMAX) :: acoef, bcoef
1455      real   , dimension(0:NOMAX,0:NOMAX) :: filter
1456!       Working space.
1457      real   , dimension(0:NOMAX) :: alpha, beta
1458
1459      real   :: DTT
1460
1461      DTT = ABS(DT)
1462      PI = 2*DASIN(1.D0)
1463      IOTA = CMPLX(0.,1.)
1464
1465!       Filtering Parameters (derived).
1466      THETAC = 2*PI*DTT/(TAUC)
1467      MUC = tan(THETAC/2)
1468      FC = THETAC/(2*PI)
1469
1470!     Clear the arrays.
1471    DO NC=0,NOMAX
1472       ACOEF(NC) = 0.
1473       BCOEF(NC) = 0.
1474       ALPHA(NC) = 0.
1475       BETA (NC) = 0.
1476       FROW (NC) = 0.
1477       DO NR=0,NOMAX
1478          FILTER(NR,NC) = 0.
1479       ENDDO
1480    ENDDO
1481
1482!     Fill up the Filter Matrix.
1483    FILTER(0,0) = 1.
1484
1485!     Get the coefficients of the Filter.
1486    IF ( ICTYPE.eq.2 ) THEN
1487       CALL RHOCOF(NORDER,NOMAX,MUC, ACOEF,BCOEF)
1488    ENDIF
1489
1490    DO 100 NROW=1,NSTEP
1491
1492       IF ( ICTYPE.eq.1 ) THEN
1493          NORD = MIN(NROW,NORDER)
1494          IF ( NORD.le.NORDER) THEN
1495             CALL RHOCOF(NORD,NOMAX,MUC, ACOEF,BCOEF)
1496          ENDIF
1497       ENDIF
1498
1499       DO K=0,NROW
1500          ALPHA(K) = ACOEF(NROW-K)
1501          IF(K.lt.NROW) BETA(K) = BCOEF(NROW-K)
1502       ENDDO
1503
1504!        Correction for terms of negative index.
1505       IF ( ICTYPE.eq.2 ) THEN
1506          IF ( NROW.lt.NORDER ) THEN
1507             CN = 0.
1508             DO NN=NROW+1,NORDER
1509                CN = CN + (ACOEF(NN)+BCOEF(NN))
1510             ENDDO
1511             ALPHA(0) = ALPHA(0) + CN
1512          ENDIF
1513       ENDIF
1514
1515!       Check sum of ALPHAs and BETAs = 1
1516      SUMAB = 0.
1517      DO NN=0,NROW
1518        SUMAB = SUMAB + ALPHA(NN)
1519          IF(NN.lt.NROW) SUMAB = SUMAB + BETA(NN)
1520      ENDDO
1521
1522      DO KK=0,NROW-1
1523         SUMBF = 0.
1524         DO LL=0,NROW-1
1525            SUMBF = SUMBF + BETA(LL)*FILTER(LL,KK)
1526         ENDDO
1527         FILTER(NROW,KK) = ALPHA(KK)+SUMBF
1528      ENDDO
1529      FILTER(NROW,NROW) = ALPHA(NROW)
1530
1531!       Check sum of row elements = 1
1532      SUMROW = 0.
1533      DO NN=0,NROW
1534        SUMROW = SUMROW + FILTER(NROW,NN)
1535      ENDDO
1536
1537100 CONTINUE
1538
1539      DO NC=0,NSTEP
1540        FROW(NC) = FILTER(NSTEP,NC)
1541      ENDDO
1542
1543      RETURN
1544
1545   END SUBROUTINE rhofil
1546
1547
1548   SUBROUTINE rhocof(nord, nomax, muc, ca, cb)
1549
1550!     Get the coefficients of the RHO Filter
1551
1552!      IMPLICIT DOUBLE PRECISION (A-H,O-Z)
1553      IMPLICIT NONE
1554
1555      ! Arguments
1556      integer, intent(in)      :: nord, nomax
1557      real, dimension(0:nomax) :: ca, cb
1558
1559      ! Functions
1560      double precision, external :: cnr
1561
1562      ! Local variables
1563      INTEGER                  :: nn
1564      COMPLEX                  :: IOTA
1565      DOUBLE PRECISION         :: MUC, ZN
1566      DOUBLE PRECISION         :: pi, root2, rn, sigma, gain, sumcof
1567
1568      PI = 2*ASIN(1.)
1569      ROOT2 = SQRT(2.)
1570      IOTA = (0.,1.)
1571
1572      RN = 1./FLOAT(NORD)
1573      SIGMA = 1./( SQRT(2.**RN-1.) )
1574
1575      GAIN  = (MUC*SIGMA/(1+MUC*SIGMA))**NORD
1576      ZN = (1-MUC*SIGMA)/(1+MUC*SIGMA)
1577
1578      DO NN=0,NORD
1579        CA(NN) = CNR(NORD,NN)*GAIN
1580        IF(NN.gt.0) CB(NN) = -CNR(NORD,NN)*(-ZN)**NN
1581      ENDDO
1582
1583!     Check sum of coefficients = 1
1584      SUMCOF = 0.
1585      DO NN=0,NORD
1586        SUMCOF = SUMCOF + CA(NN)
1587        IF(NN.gt.0) SUMCOF = SUMCOF + CB(NN)
1588      ENDDO
1589
1590      RETURN
1591
1592   END SUBROUTINE RHOCOF
1593
1594
1595   DOUBLE PRECISION FUNCTION cnr(n,r)
1596
1597   ! Binomial Coefficient (n,r).
1598
1599!      IMPLICIT DOUBLE PRECISION(C,X)
1600      IMPLICIT NONE
1601
1602      ! Arguments
1603      INTEGER , intent(in)    :: n, R
1604
1605      ! Local variables
1606      INTEGER          :: k
1607      DOUBLE PRECISION :: coeff, xn, xr, xk
1608
1609      IF ( R.eq.0 ) THEN
1610         CNR = 1.0
1611         RETURN
1612      ENDIF
1613      Coeff = 1.0
1614      XN = DFLOAT(N)
1615      XR = DFLOAT(R)
1616      DO K=1,R
1617        XK = DFLOAT(K)
1618        COEFF = COEFF * ( (XN-XR+XK)/XK )
1619      ENDDO
1620      CNR = COEFF
1621
1622      RETURN
1623
1624   END FUNCTION cnr
1625
1626
1627    SUBROUTINE optfil (grid,NH,DELTAT,NHMAX)
1628!----------------------------------------------------------------------
1629
1630!    SUBROUTINE optfil (NH,DELTAT,TAUP,TAUS,LPRINT,         &
1631!                         H,NHMAX)
1632!
1633! - Huang and Lynch optimal filter
1634!   Monthly Weather Review, Feb 1993
1635!----------------------------------------------------------
1636!       Input Parameters in List:
1637!             NH     :  Half-length of the Filter
1638!             DELTAT :  Time-step (in seconds).     
1639!             TAUP   :  Period of pass-band edge (hours).
1640!             TAUS   :  Period of stop-band edge (hours).
1641!             LPRINT :  Logical switch for messages.
1642!             NHMAX  :  Maximum permitted Half-length.
1643!
1644!       Output Parameters in List:
1645!             H      :  Impulse Response.
1646!             DP     :  Deviation in pass-band (db)
1647!             DS     :  Deviation in stop-band (db)
1648!----------------------------------------------------------
1649!
1650     USE module_domain, ONLY : domain
1651   
1652     TYPE(domain) , POINTER :: grid
1653
1654     REAL,DIMENSION( 20) :: EDGE
1655     REAL,DIMENSION( 10) :: FX, WTX, DEVIAT
1656     REAL,DIMENSION(2*NHMAX+1) :: H
1657     logical LPRINT
1658     REAL, INTENT (IN) :: DELTAT
1659     INTEGER, INTENT (IN) :: NH, NHMAX
1660!
1661         TAUP = 3.
1662         TAUS = 1.5
1663         LPRINT = .true.
1664!initialize H array
1665
1666         NL=2*NHMAX+1
1667        do 101 n=1,NL
1668          H(n)=0.
1669 101    continue
1670
1671        NFILT = 2*NH+1
1672        print *,' start optfil, NFILT=', nfilt
1673
1674!
1675! 930325 PL & XYH : the upper limit is changed from 64 to 128.
1676        IF(NFILT.LE.0 .OR. NFILT.GT.128 ) THEN
1677           WRITE(6,*) 'NH=',NH
1678       CALL wrf_error_fatal (' Sorry, error 1 in call to OPTFIL ')
1679        ENDIF
1680!
1681!       The following four should always be the same.
1682        JTYPE = 1
1683        NBANDS = 2
1684!CC     JPRINT = 0
1685        LGRID = 16
1686!
1687!       calculate transition frequencies.
1688          DT = ABS(DELTAT)
1689          FS = DT/(TAUS*3600.)
1690          FP = DT/(TAUP*3600.)
1691          IF(FS.GT.0.5) then
1692!            print *,' FS too large in OPTFIL '
1693       CALL wrf_error_fatal (' FS too large in OPTFIL ')
1694!            return
1695          end if
1696          IF(FP.LT.0.0) then
1697!            print *, ' FP too small in OPTFIL '
1698       CALL wrf_error_fatal (' FP too small in OPTFIL ')
1699!            return
1700          end if
1701!
1702!       Relative Weights in pass- and stop-bands.
1703          WTP = 1.0
1704          WTS = 1.0
1705!
1706!CC     NOTE: (FP,FC,FS) is an arithmetic progression, so
1707!CC           (1/FS,1/FC,1/FP) is a harmonic one.
1708!CC           TAUP = 1/( (1/TAUC)-(1/DTAU) )
1709!CC           TAUS = 1/( (1/TAUC)+(1/DTAU) )
1710!CC           TAUC   :  Cut-off Period (hours).
1711!CC           DTAU   :  Transition half-width (hours).
1712!CC           FC = 1/TAUC  ;  DF = 1/DTAU
1713!CC           FP = FC - DF :  FS = FC + DF
1714!
1715          IF ( LPRINT ) THEN
1716               TAUC = 2./((1/TAUS)+(1/TAUP))
1717               DTAU = 2./((1/TAUS)-(1/TAUP))
1718               FC = DT/(TAUC*3600.)
1719               DF = DT/(DTAU*3600.)
1720               WRITE(6,*) ' DT ' , dt
1721               WRITE(6,*) ' TAUS, TAUP ' , TAUS,TAUP
1722               WRITE(6,*) ' TAUC, DTAU ' , TAUC,DTAU
1723               WRITE(6,*) '   FP,   FS ' ,   FP,  FS   
1724               WRITE(6,*) '   FC,   DF ' ,   FC,  DF
1725               WRITE(6,*) '  WTS,  WTP ' ,  WTS, WTP
1726          ENDIF
1727!
1728!       Fill the control vectors for MCCPAR
1729        EDGE(1) = 0.0
1730        EDGE(2) = FP
1731        EDGE(3) = FS
1732        EDGE(4) = 0.5
1733        FX(1) = 1.0
1734        FX(2) = 0.0
1735        WTX(1) = WTP
1736        WTX(2) = WTS
1737
1738        CALL MCCPAR(NFILT,JTYPE,NBANDS,LPRINT,LGRID,       &
1739                   EDGE,FX,WTX,DEVIAT, h )
1740!
1741!       Save the deviations in the pass- and stop-bands.
1742        DP = DEVIAT(1)
1743        DS = DEVIAT(2)
1744!
1745!     Fill out the array H (only first half filled in MCCPAR).
1746      IF(MOD(NFILT,2).EQ.0) THEN
1747         NHALF = ( NFILT )/2
1748      ELSE
1749         NHALF = (NFILT+1)/2
1750      ENDIF
1751      DO 100 nn=1,NHALF
1752         H(NFILT+1-nn) = h(nn)
1753  100 CONTINUE
1754
1755!       normalize the sums to be unity
1756        sumh = 0
1757        do 150 n=1,NFILT
1758          sumh = sumh + H(n)
1759  150   continue
1760  print *,'SUMH =', sumh
1761
1762        do 200 n=1,NFILT
1763          H(n)  = H(n)/sumh
1764  200   continue
1765        do 201 n=1,NFILT
1766        grid%hcoeff(n)=H(n)
1767  201   continue
1768!       print *,'HCOEFF(n) ', grid%hcoeff
1769!
1770   END SUBROUTINE optfil
1771
1772
1773      SUBROUTINE MCCPAR (NFILT,JTYPE,NBANDS,LPRINT,LGRID,    &
1774                   EDGE,FX,WTX,DEVIAT,h )
1775
1776!      PROGRAM FOR THE DESIGN OF LINEAR PHASE FINITE IMPULSE
1777!      REPONSE (FIR) FILTERS USING THE REMEZ EXCHANGE ALGORITHM
1778!
1779!************************************************************
1780!*  Reference: McClellan, J.H., T.W. Parks and L.R.Rabiner, *
1781!*             1973:  A computer program for designing      *
1782!*             optimum FIR linear phase digital filters.    *
1783!*             IEEE Trans. on Audio and Electroacoustics,   *
1784!*             Vol AU-21, No. 6, 506-526.                   *
1785!************************************************************
1786!
1787!      THREE TYPES OF FILTERS ARE INCLUDED -- BANDPASS FILTERS
1788!      DIFFERENTIATORS, AND HILBERT TRANSFORM FILTERS
1789!
1790!---------------------------------------------------------------
1791!
1792!      COMMON /x3x/ PI2,AD,DEV,X,Y,GRID,DES,WT,ALPHA,IEXT,NFCNS,NGRID
1793      DIMENSION IEXT(66),AD(66),ALPHA(66),X(66),Y(66)
1794      DIMENSION H(66)
1795      DIMENSION DES(1045),GRID(1045),WT(1045)
1796      DIMENSION EDGE(20),FX(10),WTX(10),DEVIAT(10)
1797      DOUBLE PRECISION PI2,PI
1798      DOUBLE PRECISION AD,DEV,X,Y
1799      LOGICAL LPRINT
1800     
1801      PI  = 3.141592653589793
1802      PI2 = 6.283185307179586
1803
1804!      ......
1805
1806      NFMAX = 128
1807100      CONTINUE
1808
1809!      PROGRAM INPUT SECTION
1810
1811!CC     READ(5,*) NFILT,JTYPE,NBANDS,JPRINT,LGRID
1812
1813      IF(NFILT.GT.NFMAX.OR.NFILT.LT.3) THEN
1814         CALL wrf_error_fatal (' **** ERROR IN INPUT DATA ****' )
1815      END IF
1816      IF(NBANDS.LE.0) NBANDS = 1
1817
1818!      ....
1819
1820      IF(LGRID.LE.0) LGRID = 16
1821      JB = 2*NBANDS
1822!cc       READ(5,*) (EDGE(J),J=1,JB)
1823!cc       READ(5,*) (FX(J),J=1,NBANDS)
1824!cc       READ(5,*) (WTX(J),J=1,NBANDS)
1825      IF(JTYPE.EQ.0) THEN
1826         CALL wrf_error_fatal (' **** ERROR IN INPUT DATA ****' )
1827      END IF
1828      NEG = 1
1829      IF(JTYPE.EQ.1) NEG = 0
1830      NODD = NFILT/2
1831      NODD = NFILT-2*NODD
1832      NFCNS = NFILT/2
1833      IF(NODD.EQ.1.AND.NEG.EQ.0) NFCNS = NFCNS+1
1834
1835!      ...
1836
1837      GRID(1) = EDGE(1)
1838      DELF = LGRID*NFCNS
1839      DELF = 0.5/DELF
1840      IF(NEG.EQ.0) GOTO 135
1841      IF(EDGE(1).LT.DELF) GRID(1) = DELF
1842135      CONTINUE
1843      J = 1
1844      L = 1
1845      LBAND = 1
1846140      FUP = EDGE(L+1)
1847145      TEMP = GRID(J)
1848
1849!      ....
1850
1851      DES(J) = EFF(TEMP,FX,WTX,LBAND,JTYPE)
1852      WT(J) = WATE(TEMP,FX,WTX,LBAND,JTYPE)
1853      J = J+1
1854      GRID(J) = TEMP+DELF
1855      IF(GRID(J).GT.FUP) GOTO 150
1856      GOTO 145
1857150      GRID(J-1) = FUP
1858      DES(J-1) = EFF(FUP,FX,WTX,LBAND,JTYPE)
1859      WT(J-1) = WATE(FUP,FX,WTX,LBAND,JTYPE)
1860      LBAND = LBAND+1
1861      L = L+2
1862      IF(LBAND.GT.NBANDS) GOTO 160
1863      GRID(J) = EDGE(L)
1864      GOTO 140
1865160      NGRID = J-1
1866      IF(NEG.NE.NODD) GOTO 165
1867      IF(GRID(NGRID).GT.(0.5-DELF)) NGRID = NGRID-1
1868165      CONTINUE
1869
1870!      ......
1871
1872      IF(NEG) 170,170,180
1873170      IF(NODD.EQ.1) GOTO 200
1874      DO 175 J=1,NGRID
1875            CHANGE = DCOS(PI*GRID(J))
1876            DES(J) = DES(J)/CHANGE
1877            WT(J) = WT(J)*CHANGE
1878175      CONTINUE
1879      GOTO 200
1880180      IF(NODD.EQ.1) GOTO 190
1881      DO 185 J = 1,NGRID
1882            CHANGE = DSIN(PI*GRID(J))
1883            DES(J) = DES(J)/CHANGE
1884            WT(J)  = WT(J)*CHANGE
1885185      CONTINUE
1886      GOTO 200
1887190      DO 195 J =1,NGRID
1888            CHANGE = DSIN(PI2*GRID(J))
1889            DES(J) = DES(J)/CHANGE
1890            WT(J)  = WT(J)*CHANGE
1891195      CONTINUE
1892
1893!      ......
1894
1895200      TEMP = FLOAT(NGRID-1)/FLOAT(NFCNS)
1896      DO 210 J = 1,NFCNS
1897            IEXT(J) = (J-1)*TEMP+1
1898210      CONTINUE
1899      IEXT(NFCNS+1) = NGRID
1900      NM1 = NFCNS-1
1901      NZ  = NFCNS+1
1902
1903! CALL THE REMEZ EXCHANGE ALGORITHM TO DO THE APPROXIMATION PROBLEM
1904
1905      CALL REMEZ(EDGE,NBANDS,PI2,AD,DEV,X,Y,GRID,DES,WT,ALPHA,IEXT,NFCNS,NGRID)
1906
1907! CALCULATE THE IMPULSE RESPONSE
1908
1909      IF(NEG) 300,300,320
1910300      IF(NODD.EQ.0) GOTO 310
1911      DO 305 J=1,NM1
1912            H(J) = 0.5*ALPHA(NZ-J)
1913305      CONTINUE
1914      H(NFCNS)=ALPHA(1)
1915      GOTO 350
1916310      H(1) = 0.25*ALPHA(NFCNS)
1917      DO 315 J = 2,NM1
1918            H(J) = 0.25*(ALPHA(NZ-J)+ALPHA(NFCNS+2-J))
1919315      CONTINUE
1920      H(NFCNS) = 0.5*ALPHA(1)+0.25*ALPHA(2)
1921      GOTO 350
1922320      IF(NODD.EQ.0) GOTO 330
1923      H(1) = 0.25*ALPHA(NFCNS)
1924      H(2) = 0.25*ALPHA(NM1)
1925      DO 325 J = 3,NM1
1926            H(J) = 0.25*(ALPHA(NZ-J)-ALPHA(NFCNS+3-J))
1927325      CONTINUE
1928      H(NFCNS) = 0.5*ALPHA(1)-0.25*ALPHA(3)
1929      H(NZ) = 0.0
1930      GOTO 350
1931330      H(1) = 0.25*ALPHA(NFCNS)
1932      DO 335 J =2,NM1
1933            H(J) = 0.25*(ALPHA(NZ-J)-ALPHA(NFCNS+2-J))
1934335      CONTINUE
1935      H(NFCNS) = 0.5*ALPHA(1)-0.25*ALPHA(2)
1936
1937!   PROGRAM OUTPUT SECTION
1938
1939350   CONTINUE
1940!
1941      IF(LPRINT) THEN
1942
1943         print *, '****************************************************'
1944         print *, 'FINITE IMPULSE RESPONSE (FIR)'
1945         print *, 'LINEAR PHASE DIGITAL FILTER DESIGN'
1946         print *, 'REMEZ EXCHANGE ALGORITHM'
1947     
1948      IF(JTYPE.EQ.1) WRITE(6,365)
1949365      FORMAT(25X,'BANDPASS FILTER'/)
1950
1951      IF(JTYPE.EQ.2) WRITE(6,370)
1952370      FORMAT(25X,'DIFFERENTIATOR '/)
1953
1954      IF(JTYPE.EQ.3) WRITE(6,375)
1955375      FORMAT(25X,'HILBERT TRANSFORMER '/)
1956
1957      WRITE(6,378) NFILT
1958378      FORMAT(15X,'FILTER LENGTH =',I3/)
1959
1960      WRITE(6,380)
1961380      FORMAT(15X,'***** IMPULSE RESPONSE *****')
1962
1963      DO 381 J = 1,NFCNS
1964            K = NFILT+1-J
1965            IF(NEG.EQ.0) WRITE(6,382) J,H(J),K
1966            IF(NEG.EQ.1) WRITE(6,383) J,H(J),K
1967381      CONTINUE
1968382      FORMAT(20X,'H(',I3,') = ',E15.8,' = H(',I4,')')
1969383      FORMAT(20X,'H(',I3,') = ',E15.8,' = -H(',I4,')')
1970
1971      IF(NEG.EQ.1.AND.NODD.EQ.1) WRITE(6,384) NZ
1972384      FORMAT(20X,'H(',I3,') = 0.0')
1973
1974      DO 450 K=1,NBANDS,4
1975            KUP = K+3
1976            IF(KUP.GT.NBANDS) KUP = NBANDS
1977            print *
1978            WRITE(6,385) (J,J=K,KUP)
1979385            FORMAT(24X,4('BAND',I3,8X))
1980            WRITE(6,390) (EDGE(2*J-1),J=K,KUP)
1981390            FORMAT(2X,'LOWER BAND EDGE',5F15.8)
1982            WRITE(6,395) (EDGE(2*J),J=K,KUP)
1983395            FORMAT(2X,'UPPER BAND EDGE',5F15.8)
1984            IF(JTYPE.NE.2) WRITE(6,400) (FX(J),J=K,KUP)
1985400            FORMAT(2X,'DESIRED VALUE',2X,5F15.8)
1986            IF(JTYPE.EQ.2) WRITE(6,405) (FX(J),J=K,KUP)
1987405            FORMAT(2X,'DESIRED SLOPE',2X,5F15.8)
1988            WRITE(6,410) (WTX(J),J=K,KUP)
1989410            FORMAT(2X,'WEIGHTING',6X,5F15.8)
1990            DO 420 J = K,KUP
1991                  DEVIAT(J) = DEV/WTX(J)
1992420            CONTINUE
1993            WRITE(6,425) (DEVIAT(J),J=K,KUP)
1994425            FORMAT(2X,'DEVIATION',6X,5F15.8)
1995            IF(JTYPE.NE.1) GOTO 450
1996            DO 430 J = K,KUP
1997                  DEVIAT(J) = 20.0*ALOG10(DEVIAT(J))
1998430            CONTINUE
1999            WRITE(6,435) (DEVIAT(J),J=K,KUP)
2000435            FORMAT(2X,'DEVIATION IN DB',5F15.8)
2001450      CONTINUE
2002      print *, 'EXTREMAL FREQUENCIES'
2003      WRITE(6,455) (GRID(IEXT(J)),J=1,NZ)
2004455      FORMAT((2X,5F15.7))
2005      WRITE(6,460)
2006460      FORMAT(1X,70(1H*))
2007!
2008      ENDIF
2009!
2010!CC     IF(NFILT.NE.0) GOTO 100  ! removal of re-run loop.
2011!
2012   END SUBROUTINE mccpar
2013
2014
2015      FUNCTION EFF(TEMP,FX,WTX,LBAND,JTYPE)
2016         DIMENSION FX(5),WTX(5)
2017         IF(JTYPE.EQ.2) GOTO 1
2018         EFF = FX(LBAND)
2019         RETURN
20201        EFF = FX(LBAND)*TEMP
2021      END FUNCTION eff
2022
2023
2024      FUNCTION WATE(TEMP,FX,WTX,LBAND,JTYPE)
2025         DIMENSION FX(5),WTX(5)
2026         IF(JTYPE.EQ.2) GOTO 1
2027         WATE = WTX(LBAND)
2028         RETURN
20291        IF(FX(LBAND).LT.0.0001) GOTO 2
2030         WATE = WTX(LBAND)/TEMP
2031         RETURN
20322        WATE = WTX(LBAND)
2033      END FUNCTION wate
2034
2035
2036!      SUBROUTINE ERROR
2037!!         WRITE(6,*)' **** ERROR IN INPUT DATA ****'
2038!          CALL wrf_error_fatal (' **** ERROR IN INPUT DATA ****' )
2039!      END SUBROUTINE error
2040
2041     
2042      SUBROUTINE REMEZ(EDGE,NBANDS,PI2,AD,DEV,X,Y,GRID,DES,WT,ALPHA,IEXT,NFCNS,NGRID)
2043!  THIS SUBROUTINE IMPLEMENTS THE REMEZ EXCHANGE ALGORITHM
2044!  FOR THE WEIGHTED CHEBCHEV APPROXIMATION OF A CONTINUOUS
2045!  FUNCTION WITH A SUM OF COSINES. INPUTS TO THE SUBROUTINE
2046!  ARE A DENSE GRID WHICH REPLACES THE FREQUENCY AXIS, THE
2047!  DESIRED FUNCTION ON THIS GRID, THE WEIGHT FUNCTION ON THE
2048!  GRID, THE NUMBER OF COSINES, AND THE INITIAL GUESS OF THE
2049!  EXTREMAL FREQUENCIES. THE PROGRAM MINIMIZES THE CHEBYSHEV
2050!  ERROR BY DETERMINING THE BEST LOCATION OF THE EXTREMAL
2051!  FREQUENCIES (POINTS OF MAXIMUM ERROR) AND THEN CALCULATES
2052!  THE COEFFICIENTS OF THE BEST APPROXIMATION.
2053!
2054!      COMMON /x3x/ PI2,AD,DEV,X,Y,GRID,DES,WT,ALPHA,IEXT,NFCNS,NGRID
2055      DIMENSION EDGE(20)
2056      DIMENSION IEXT(66),AD(66),ALPHA(66),X(66),Y(66)
2057      DIMENSION DES(1045),GRID(1045),WT(1045)
2058      DIMENSION A(66),P(65),Q(65)
2059      DOUBLE PRECISION PI2,DNUM,DDEN,DTEMP,A,P,Q
2060      DOUBLE PRECISION AD,DEV,X,Y
2061      DOUBLE PRECISION, EXTERNAL :: D, GEE
2062!
2063!  THE PROGRAM ALLOWS A MAXIMUM NUMBER OF ITERATIONS OF 25
2064!
2065      ITRMAX=25
2066      DEVL=-1.0
2067      NZ=NFCNS+1
2068      NZZ=NFCNS+2
2069      NITER=0
2070  100 CONTINUE
2071      IEXT(NZZ)=NGRID+1
2072      NITER=NITER+1
2073      IF(NITER.GT.ITRMAX) GO TO 400
2074      DO 110 J=1,NZ
2075      DTEMP=GRID(IEXT(J))
2076      DTEMP=DCOS(DTEMP*PI2)
2077  110 X(J)=DTEMP
2078      JET=(NFCNS-1)/15+1
2079      DO 120 J=1,NZ
2080  120 AD(J)=D(J,NZ,JET,X)
2081      DNUM=0.0
2082      DDEN=0.0
2083      K=1
2084      DO 130 J=1,NZ
2085      L=IEXT(J)
2086      DTEMP=AD(J)*DES(L)
2087      DNUM=DNUM+DTEMP
2088      DTEMP=K*AD(J)/WT(L)
2089      DDEN=DDEN+DTEMP
2090  130 K=-K
2091      DEV=DNUM/DDEN
2092      NU=1
2093      IF(DEV.GT.0.0) NU=-1
2094      DEV=-NU*DEV
2095      K=NU
2096      DO 140 J=1,NZ
2097      L=IEXT(J)
2098      DTEMP=K*DEV/WT(L)
2099      Y(J)=DES(L)+DTEMP
2100  140 K=-K
2101      IF(DEV.GE.DEVL) GO TO 150
2102      WRITE(6,*) ' ******** FAILURE TO CONVERGE *********** '
2103      WRITE(6,*) ' PROBABLE CAUSE IS MACHINE ROUNDING ERROR '
2104      WRITE(6,*) ' THE IMPULSE RESPONSE MAY BE CORRECT '
2105      WRITE(6,*) ' CHECK WITH A FREQUENCY RESPONSE '
2106      WRITE(6,*) ' **************************************** '
2107      GO TO 400
2108  150 DEVL=DEV
2109      JCHNGE=0
2110      K1=IEXT(1)
2111      KNZ=IEXT(NZ)
2112      KLOW=0
2113      NUT=-NU
2114      J=1
2115!
2116!  SEARCH FOR THE EXTERMAL FREQUENCIES OF THE BEST
2117!  APPROXIMATION.
2118
2119  200 IF(J.EQ.NZZ) YNZ=COMP
2120      IF(J.GE.NZZ) GO TO 300
2121      KUP=IEXT(J+1)
2122      L=IEXT(J)+1
2123      NUT=-NUT
2124      IF(J.EQ.2) Y1=COMP
2125      COMP=DEV
2126      IF(L.GE.KUP) GO TO 220
2127      ERR=GEE(L,NZ,GRID,PI2,X,Y,AD)
2128      ERR=(ERR-DES(L))*WT(L)
2129      DTEMP=NUT*ERR-COMP
2130      IF(DTEMP.LE.0.0) GO TO 220
2131      COMP=NUT*ERR
2132  210 L=L+1
2133      IF(L.GE.KUP) GO TO 215
2134      ERR=GEE(L,NZ,GRID,PI2,X,Y,AD)
2135      ERR=(ERR-DES(L))*WT(L)
2136      DTEMP=NUT*ERR-COMP
2137      IF(DTEMP.LE.0.0) GO TO 215
2138      COMP=NUT*ERR
2139      GO TO 210
2140  215 IEXT(J)=L-1
2141      J=J+1
2142      KLOW=L-1
2143      JCHNGE=JCHNGE+1
2144      GO TO 200
2145  220 L=L-1
2146  225 L=L-1
2147      IF(L.LE.KLOW) GO TO 250
2148      ERR=GEE(L,NZ,GRID,PI2,X,Y,AD)
2149      ERR=(ERR-DES(L))*WT(L)
2150      DTEMP=NUT*ERR-COMP
2151      IF(DTEMP.GT.0.0) GO TO 230
2152      IF(JCHNGE.LE.0) GO TO 225
2153      GO TO 260
2154  230 COMP=NUT*ERR
2155  235 L=L-1
2156      IF(L.LE.KLOW) GO TO 240
2157      ERR=GEE(L,NZ,GRID,PI2,X,Y,AD)
2158      ERR=(ERR-DES(L))*WT(L)
2159      DTEMP=NUT*ERR-COMP
2160      IF(DTEMP.LE.0.0) GO TO 240
2161      COMP=NUT*ERR
2162      GO TO 235
2163  240 KLOW=IEXT(J)
2164      IEXT(J)=L+1
2165      J=J+1
2166      JCHNGE=JCHNGE+1
2167      GO TO 200
2168  250 L=IEXT(J)+1
2169      IF(JCHNGE.GT.0) GO TO 215
2170  255 L=L+1
2171      IF(L.GE.KUP) GO TO 260
2172      ERR=GEE(L,NZ,GRID,PI2,X,Y,AD)
2173      ERR=(ERR-DES(L))*WT(L)
2174      DTEMP=NUT*ERR-COMP
2175      IF(DTEMP.LE.0.0) GO TO 255
2176      COMP=NUT*ERR
2177      GO TO 210
2178  260 KLOW=IEXT(J)
2179      J=J+1
2180      GO TO 200
2181  300 IF(J.GT.NZZ) GO TO 320
2182      IF(K1.GT.IEXT(1)) K1=IEXT(1)
2183      IF(KNZ.LT.IEXT(NZ)) KNZ=IEXT(NZ)
2184      NUT1=NUT
2185      NUT=-NU
2186      L=0
2187      KUP=K1
2188      COMP=YNZ*(1.00001)
2189      LUCK=1
2190  310 L=L+1
2191      IF(L.GE.KUP) GO TO 315
2192      ERR=GEE(L,NZ,GRID,PI2,X,Y,AD)
2193      ERR=(ERR-DES(L))*WT(L)
2194      DTEMP=NUT*ERR-COMP
2195      IF(DTEMP.LE.0.0) GO TO 310
2196      COMP=NUT*ERR
2197      J=NZZ
2198      GO TO 210
2199  315 LUCK=6
2200      GO TO 325
2201  320 IF(LUCK.GT.9) GO TO 350
2202      IF(COMP.GT.Y1) Y1=COMP
2203      K1=IEXT(NZZ)
2204  325 L=NGRID+1
2205      KLOW=KNZ
2206      NUT=-NUT1
2207      COMP=Y1*(1.00001)
2208  330 L=L-1
2209      IF(L.LE.KLOW) GO TO 340
2210      ERR=GEE(L,NZ,GRID,PI2,X,Y,AD)
2211      ERR=(ERR-DES(L))*WT(L)
2212      DTEMP=NUT*ERR-COMP
2213      IF(DTEMP.LE.0.0) GO TO 330
2214      J=NZZ
2215      COMP=NUT*ERR
2216      LUCK=LUCK+10
2217      GO TO 235
2218  340 IF(LUCK.EQ.6) GO TO 370
2219      DO 345 J=1,NFCNS
2220  345 IEXT(NZZ-J)=IEXT(NZ-J)
2221      IEXT(1)=K1
2222      GO TO 100
2223  350 KN=IEXT(NZZ)
2224      DO 360 J=1,NFCNS
2225  360 IEXT(J)=IEXT(J+1)
2226      IEXT(NZ)=KN
2227      GO TO 100
2228  370 IF(JCHNGE.GT.0) GO TO 100
2229!
2230!  CALCULATION OF THE COEFFICIENTS OF THE BEST APPROXIMATION
2231!  USING THE INVERSE DISCRETE FOURIER TRANSFORM.
2232!     
2233  400 CONTINUE
2234      NM1=NFCNS-1
2235      FSH=1.0E-06
2236      GTEMP=GRID(1)
2237      X(NZZ)=-2.0
2238      CN=2*NFCNS-1
2239      DELF=1.0/CN
2240      L=1
2241      KKK=0
2242      IF(EDGE(1).EQ.0.0.AND.EDGE(2*NBANDS).EQ.0.5) KKK=1
2243      IF(NFCNS.LE.3) KKK=1
2244      IF(KKK.EQ.1) GO TO 405
2245      DTEMP=DCOS(PI2*GRID(1))
2246      DNUM=DCOS(PI2*GRID(NGRID))
2247      AA=2.0/(DTEMP-DNUM)
2248      BB=-(DTEMP+DNUM)/(DTEMP-DNUM)
2249  405 CONTINUE
2250      DO 430 J=1,NFCNS
2251      FT=(J-1)*DELF
2252      XT=DCOS(PI2*FT)
2253      IF(KKK.EQ.1) GO TO 410
2254      XT=(XT-BB)/AA
2255! original :      FT=ARCOS(XT)/PI2
2256      FT=ACOS(XT)/PI2
2257  410 XE=X(L)
2258      IF(XT.GT.XE) GO TO 420
2259      IF((XE-XT).LT.FSH) GO TO 415
2260      L=L+1
2261      GO TO 410
2262  415 A(J)=Y(L)
2263      GO TO 425
2264  420 IF((XT-XE).LT.FSH) GO TO 415
2265      GRID(1)=FT
2266      A(J)=GEE(1,NZ,GRID,PI2,X,Y,AD)
2267  425 CONTINUE
2268      IF(L.GT.1) L=L-1
2269  430 CONTINUE
2270      GRID(1)=GTEMP
2271      DDEN=PI2/CN
2272      DO 510 J=1,NFCNS
2273      DTEMP=0.0
2274      DNUM=(J-1)*DDEN
2275      IF(NM1.LT.1) GO TO 505
2276      DO 500 K=1,NM1
2277  500 DTEMP=DTEMP+A(K+1)*DCOS(DNUM*K)
2278  505 DTEMP=2.0*DTEMP+A(1)
2279  510 ALPHA(J)=DTEMP
2280      DO 550 J=2,NFCNS
2281  550 ALPHA(J)=2*ALPHA(J)/CN
2282      ALPHA(1)=ALPHA(1)/CN
2283      IF(KKK.EQ.1) GO TO 545
2284      P(1)=2.0*ALPHA(NFCNS)*BB+ALPHA(NM1)
2285      P(2)=2.0*AA*ALPHA(NFCNS)
2286      Q(1)=ALPHA(NFCNS-2)-ALPHA(NFCNS)
2287      DO 540 J=2,NM1
2288      IF(J.LT.NM1) GO TO 515
2289      AA=0.5*AA
2290      BB=0.5*BB
2291  515 CONTINUE
2292      P(J+1)=0.0
2293      DO 520 K=1,J
2294      A(K)=P(K)
2295  520 P(K)=2.0*BB*A(K)
2296      P(2)=P(2)+A(1)*2.0*AA
2297      JM1=J-1
2298      DO 525 K=1,JM1
2299  525 P(K)=P(K)+Q(K)+AA*A(K+1)
2300      JP1=J+1
2301      DO 530 K=3,JP1
2302  530 P(K)=P(K)+AA*A(K-1)
2303      IF(J.EQ.NM1) GO TO 540
2304      DO 535 K=1,J
2305  535 Q(K)=-A(K)
2306      Q(1)=Q(1)+ALPHA(NFCNS-1-J)
2307  540 CONTINUE
2308      DO 543 J=1,NFCNS
2309  543 ALPHA(J)=P(J)
2310  545 CONTINUE
2311      IF(NFCNS.GT.3) RETURN
2312      ALPHA(NFCNS+1)=0.0
2313      ALPHA(NFCNS+2)=0.0
2314   END SUBROUTINE remez
2315
2316   DOUBLE PRECISION FUNCTION D(K,N,M,X)
2317!      COMMON /x3x/ PI2,AD,DEV,X,Y,GRID,DES,WT,ALPHA,IEXT,NFCNS,NGRID
2318      DIMENSION IEXT(66),AD(66),ALPHA(66),X(66),Y(66)
2319      DIMENSION DES(1045),GRID(1045),WT(1045)
2320      DOUBLE PRECISION AD,DEV,X,Y
2321      DOUBLE PRECISION Q
2322      DOUBLE PRECISION PI2
2323      D = 1.0
2324      Q = X(K)
2325      DO 3 L = 1,M
2326      DO 2 J = L,N,M
2327            IF(J-K) 1,2,1
23281                  D = 2.0*D*(Q-X(J))
23292      CONTINUE
23303      CONTINUE
2331      D = 1.0/D
2332   END FUNCTION D
2333
2334
2335   DOUBLE PRECISION FUNCTION GEE(K,N,GRID,PI2,X,Y,AD)
2336!      COMMON /x3x/ PI2,AD,DEV,X,Y,GRID,DES,WT,ALPHA,IEXT,NFCNS,NGRID
2337      DIMENSION IEXT(66),AD(66),ALPHA(66),X(66),Y(66)
2338      DIMENSION DES(1045),GRID(1045),WT(1045)
2339      DOUBLE PRECISION AD,DEV,X,Y
2340      DOUBLE PRECISION P,C,D,XF
2341      DOUBLE PRECISION PI2
2342      P = 0.0
2343      XF = GRID(K)
2344      XF = DCOS(PI2*XF)
2345      D = 0.0
2346      DO 1 J =1,N
2347            C = XF-X(J)
2348            C = AD(J)/C
2349            D = D+C
2350            P = P+C*Y(J)
23511      CONTINUE
2352      GEE = P/D
2353   END FUNCTION GEE
2354
2355      REAL FUNCTION RSLF(P,T)
2356
2357      IMPLICIT NONE
2358      REAL, INTENT(IN):: P, T
2359      REAL:: ESL,X
2360      REAL, PARAMETER:: C0= .611583699E03
2361      REAL, PARAMETER:: C1= .444606896E02
2362      REAL, PARAMETER:: C2= .143177157E01
2363      REAL, PARAMETER:: C3= .264224321E-1
2364      REAL, PARAMETER:: C4= .299291081E-3
2365      REAL, PARAMETER:: C5= .203154182E-5
2366      REAL, PARAMETER:: C6= .702620698E-8
2367      REAL, PARAMETER:: C7= .379534310E-11
2368      REAL, PARAMETER:: C8=-.321582393E-13
2369
2370      X=MAX(-80.,T-273.16)
2371
2372!      ESL=612.2*EXP(17.67*X/(T-29.65))
2373      ESL=C0+X*(C1+X*(C2+X*(C3+X*(C4+X*(C5+X*(C6+X*(C7+X*C8)))))))
2374      RSLF=.622*ESL/(P-ESL)
2375
2376      END FUNCTION RSLF
2377
2378!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
2379! DFI startfwd group of functions
2380!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
2381
2382   SUBROUTINE wrf_dfi_startfwd_init ( )
2383
2384     USE module_domain, ONLY : domain, head_grid, domain_get_stop_time, domain_get_start_time, set_current_grid_ptr
2385     USE module_utility
2386     
2387     IMPLICIT NONE
2388
2389     INTERFACE
2390        SUBROUTINE dfi_startfwd_init_recurse(grid)
2391          USE module_domain, ONLY : domain
2392          TYPE (domain), POINTER :: grid
2393        END SUBROUTINE dfi_startfwd_init_recurse
2394     END INTERFACE
2395
2396     ! Now, setup all nests
2397
2398     CALL dfi_startfwd_init_recurse(head_grid)
2399     
2400     CALL set_current_grid_ptr( head_grid )
2401
2402   END SUBROUTINE wrf_dfi_startfwd_init
2403
2404
2405   RECURSIVE SUBROUTINE dfi_startfwd_init_recurse(grid)
2406
2407     USE module_domain, ONLY : domain, head_grid, domain_get_stop_time, domain_get_start_time, max_nests, set_current_grid_ptr
2408
2409     IMPLICIT NONE
2410
2411      INTERFACE
2412         SUBROUTINE dfi_startfwd_init(grid)
2413            USE module_domain, ONLY : domain
2414            TYPE (domain), POINTER :: grid
2415         END SUBROUTINE dfi_startfwd_init
2416      END INTERFACE
2417
2418     INTEGER :: kid
2419     TYPE (domain), POINTER :: grid
2420     TYPE (domain), POINTER :: grid_ptr
2421   
2422     grid_ptr => grid
2423
2424     DO WHILE ( ASSOCIATED( grid_ptr ) )
2425        !
2426        ! Assure that time-step is set back to positive
2427        !   for this forward step.
2428        !
2429        grid_ptr%dt = abs(grid_ptr%dt)
2430        grid_ptr%time_step = abs(grid_ptr%time_step)
2431        CALL set_current_grid_ptr( grid_ptr )
2432        CALL dfi_startfwd_init( grid_ptr )
2433        DO kid = 1, max_nests
2434           IF ( ASSOCIATED( grid_ptr%nests(kid)%ptr ) ) THEN
2435              CALL dfi_startfwd_init_recurse(grid_ptr%nests(kid)%ptr)
2436           ENDIF
2437        END DO
2438        grid_ptr => grid_ptr%sibling
2439     END DO
2440     
2441   END SUBROUTINE dfi_startfwd_init_recurse
2442
2443
2444   SUBROUTINE dfi_startfwd_init ( grid )
2445
2446      USE module_domain, ONLY : domain, head_grid, domain_get_stop_time, domain_get_start_time
2447      USE module_utility
2448      USE module_state_description
2449
2450      IMPLICIT NONE
2451
2452      TYPE (domain) , POINTER                 :: grid
2453      INTEGER rc
2454
2455      INTERFACE
2456         SUBROUTINE Setup_Timekeeping(grid)
2457            USE module_domain, ONLY : domain
2458            TYPE (domain), POINTER :: grid
2459         END SUBROUTINE Setup_Timekeeping
2460
2461      END INTERFACE
2462
2463      grid%dfi_stage = DFI_STARTFWD
2464
2465#if (EM_CORE == 1)
2466      ! No need for adaptive time-step
2467      CALL nl_set_use_adaptive_time_step( grid%id, .false. )
2468#endif
2469
2470      CALL Setup_Timekeeping (grid)
2471      grid%start_subtime = domain_get_start_time ( head_grid )
2472      grid%stop_subtime = domain_get_stop_time ( head_grid )
2473
2474      CALL WRFU_ClockSet(grid%domain_clock, currTime=grid%start_subtime, rc=rc)
2475
2476   END SUBROUTINE dfi_startfwd_init
2477
2478!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
2479! DFI startbck group of functions
2480!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
2481
2482   SUBROUTINE wrf_dfi_startbck_init ( )
2483
2484     USE module_domain, ONLY : domain, head_grid, domain_get_stop_time, domain_get_start_time, set_current_grid_ptr
2485     USE module_utility
2486     
2487     IMPLICIT NONE
2488
2489     INTERFACE
2490        SUBROUTINE dfi_startbck_init_recurse(grid)
2491          USE module_domain, ONLY : domain
2492          TYPE (domain), POINTER :: grid
2493        END SUBROUTINE dfi_startbck_init_recurse
2494     END INTERFACE
2495
2496     ! Now, setup all nests
2497
2498     CALL dfi_startbck_init_recurse(head_grid)
2499     
2500     CALL set_current_grid_ptr( head_grid )
2501
2502   END SUBROUTINE wrf_dfi_startbck_init
2503
2504
2505   RECURSIVE SUBROUTINE dfi_startbck_init_recurse(grid)
2506
2507     USE module_domain, ONLY : domain, head_grid, domain_get_stop_time, domain_get_start_time, max_nests, set_current_grid_ptr
2508
2509     IMPLICIT NONE
2510
2511      INTERFACE
2512         SUBROUTINE dfi_startbck_init(grid)
2513            USE module_domain, ONLY : domain
2514            TYPE (domain), POINTER :: grid
2515         END SUBROUTINE dfi_startbck_init
2516      END INTERFACE
2517
2518     INTEGER :: kid
2519     TYPE (domain), POINTER :: grid
2520     TYPE (domain), POINTER :: grid_ptr
2521   
2522     grid_ptr => grid
2523
2524     DO WHILE ( ASSOCIATED( grid_ptr ) )
2525        !
2526        ! Assure that time-step is set back to positive
2527        !   for this forward step.
2528        !
2529        grid_ptr%dt = abs(grid_ptr%dt)
2530        grid_ptr%time_step = abs(grid_ptr%time_step)
2531        CALL set_current_grid_ptr( grid_ptr )
2532        CALL dfi_startbck_init( grid_ptr )
2533        DO kid = 1, max_nests
2534           IF ( ASSOCIATED( grid_ptr%nests(kid)%ptr ) ) THEN
2535              CALL dfi_startbck_init_recurse(grid_ptr%nests(kid)%ptr)
2536           ENDIF
2537        END DO
2538        grid_ptr => grid_ptr%sibling
2539     END DO
2540     
2541   END SUBROUTINE dfi_startbck_init_recurse
2542
2543
2544   SUBROUTINE dfi_startbck_init ( grid )
2545
2546      USE module_domain, ONLY : domain, head_grid, domain_get_stop_time, domain_get_start_time
2547      USE module_utility
2548      USE module_state_description
2549
2550      IMPLICIT NONE
2551
2552      TYPE (domain) , POINTER                 :: grid
2553      INTEGER rc
2554
2555      INTERFACE
2556         SUBROUTINE Setup_Timekeeping(grid)
2557            USE module_domain, ONLY : domain
2558            TYPE (domain), POINTER :: grid
2559         END SUBROUTINE Setup_Timekeeping
2560
2561      END INTERFACE
2562
2563      grid%dfi_stage = DFI_STARTBCK
2564
2565      ! set physics options to zero
2566      CALL nl_set_mp_physics( grid%id, 0 )
2567      CALL nl_set_ra_lw_physics( grid%id, 0 )
2568      CALL nl_set_ra_sw_physics( grid%id, 0 )
2569      CALL nl_set_sf_surface_physics( grid%id, 0 )
2570      CALL nl_set_sf_sfclay_physics( grid%id, 0 )
2571      CALL nl_set_sf_urban_physics( grid%id, 0 )
2572      CALL nl_set_bl_pbl_physics( grid%id, 0 )
2573      CALL nl_set_cu_physics( grid%id, 0 )
2574      CALL nl_set_damp_opt( grid%id, 0 )
2575      CALL nl_set_sst_update( grid%id, 0 )
2576      CALL nl_set_gwd_opt( grid%id, 0 )
2577#if (EM_CORE == 1)
2578      CALL nl_set_diff_6th_opt( grid%id, 0 )
2579      CALL nl_set_use_adaptive_time_step( grid%id, .false. )
2580#endif
2581      CALL nl_set_feedback( grid%id, 0 )
2582#if (EM_CORE == 1)
2583      ! set bc
2584      CALL nl_set_constant_bc( grid%id, head_grid%constant_bc)
2585#endif
2586
2587#ifdef WRF_CHEM
2588      ! set chemistry option to zero
2589      CALL nl_set_chem_opt (grid%id, 0)
2590      CALL nl_set_aer_ra_feedback (grid%id, 0)
2591      CALL nl_set_io_form_auxinput5 (grid%id, 0)
2592      CALL nl_set_io_form_auxinput7 (grid%id, 0)
2593      CALL nl_set_io_form_auxinput8 (grid%id, 0)
2594#endif
2595
2596#if (EM_CORE == 1)
2597      ! set diffusion to zero for backward integration
2598      CALL nl_set_km_opt( grid%id, grid%km_opt_dfi)
2599      CALL nl_set_moist_adv_dfi_opt( grid%id, grid%moist_adv_dfi_opt)
2600      IF ( grid%moist_adv_opt == 2 ) THEN
2601         CALL nl_set_moist_adv_opt( grid%id, 0)
2602      ENDIF
2603#endif
2604
2605      !tgs need to call start_domain here to reset bc initialization for
2606      !      negative dt, but only for outer domain.
2607      if (grid%id == 1) then
2608        CALL start_domain ( grid , .TRUE. )
2609      endif
2610
2611      ! Call wrf_run to advance forward 1 step
2612
2613      ! Negate time step
2614      CALL nl_set_time_step ( grid%id, -grid%time_step )
2615
2616      CALL Setup_Timekeeping (grid)
2617
2618      grid%start_subtime = domain_get_start_time ( grid )
2619      grid%stop_subtime = domain_get_stop_time ( grid )
2620
2621      CALL WRFU_ClockSet(grid%domain_clock, currTime=grid%start_subtime, rc=rc)
2622
2623   END SUBROUTINE dfi_startbck_init
2624
2625
2626   SUBROUTINE wrf_dfi_bck_init ( )
2627
2628     USE module_domain, ONLY : domain, head_grid, domain_get_stop_time, domain_get_start_time
2629     USE module_utility
2630     USE module_state_description
2631     
2632     IMPLICIT NONE
2633
2634     INTERFACE
2635        SUBROUTINE dfi_bck_init_recurse(grid)
2636          USE module_domain, ONLY : domain
2637          TYPE (domain), POINTER :: grid
2638        END SUBROUTINE dfi_bck_init_recurse
2639     END INTERFACE
2640
2641     ! We can only call dfi_bck_init for the head_grid
2642     !    since nests have not been instantiated at this point,
2643     !    so, dfi_bck_init will need to be called for each
2644     !    nest from integrate.
2645     CALL dfi_bck_init_recurse(head_grid)
2646
2647   END SUBROUTINE wrf_dfi_bck_init
2648
2649   RECURSIVE SUBROUTINE dfi_bck_init_recurse(grid)
2650
2651     USE module_domain, ONLY : domain, domain_get_stop_time, domain_get_start_time, max_nests, set_current_grid_ptr
2652
2653     IMPLICIT NONE
2654
2655      INTERFACE
2656         SUBROUTINE dfi_bck_init(grid)
2657            USE module_domain, ONLY : domain
2658            TYPE (domain), POINTER :: grid
2659         END SUBROUTINE dfi_bck_init
2660      END INTERFACE
2661
2662     INTEGER :: kid
2663     TYPE (domain), POINTER :: grid
2664     TYPE (domain), POINTER :: grid_ptr
2665   
2666     grid_ptr => grid
2667
2668     DO WHILE ( ASSOCIATED( grid_ptr ) )
2669        !
2670        ! Assure that time-step is set back to positive
2671        !   for this forward step.
2672        !
2673        grid_ptr%dt = abs(grid_ptr%dt)
2674        grid_ptr%time_step = abs(grid_ptr%time_step)
2675        CALL set_current_grid_ptr( grid_ptr )
2676        CALL dfi_bck_init( grid_ptr )
2677        DO kid = 1, max_nests
2678           IF ( ASSOCIATED( grid_ptr%nests(kid)%ptr ) ) THEN
2679              CALL dfi_bck_init_recurse(grid_ptr%nests(kid)%ptr)
2680           ENDIF
2681        END DO
2682        grid_ptr => grid_ptr%sibling
2683     END DO
2684     
2685   END SUBROUTINE dfi_bck_init_recurse
2686
2687!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
2688! DFI forward initialization group of functions
2689!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
2690
2691   SUBROUTINE wrf_dfi_fwd_init ( )
2692
2693     USE module_domain, ONLY : domain, head_grid, domain_get_stop_time, domain_get_start_time, set_current_grid_ptr
2694     USE module_utility
2695     
2696     IMPLICIT NONE
2697
2698     INTERFACE
2699        SUBROUTINE dfi_fwd_init_recurse(grid)
2700          USE module_domain, ONLY : domain
2701          TYPE (domain), POINTER :: grid
2702        END SUBROUTINE dfi_fwd_init_recurse
2703     END INTERFACE
2704
2705     ! Now, setup all nests
2706
2707     CALL dfi_fwd_init_recurse(head_grid)
2708     
2709     CALL set_current_grid_ptr( head_grid )
2710
2711   END SUBROUTINE wrf_dfi_fwd_init
2712
2713   RECURSIVE SUBROUTINE dfi_fwd_init_recurse(grid)
2714
2715     USE module_domain, ONLY : domain, head_grid, domain_get_stop_time, domain_get_start_time, max_nests, set_current_grid_ptr
2716
2717     IMPLICIT NONE
2718
2719      INTERFACE
2720         SUBROUTINE dfi_fwd_init(grid)
2721            USE module_domain, ONLY : domain
2722            TYPE (domain), POINTER :: grid
2723         END SUBROUTINE dfi_fwd_init
2724      END INTERFACE
2725
2726     INTEGER :: kid
2727     TYPE (domain), POINTER :: grid
2728     TYPE (domain), POINTER :: grid_ptr
2729   
2730     grid_ptr => grid
2731
2732     DO WHILE ( ASSOCIATED( grid_ptr ) )
2733        !
2734        ! Assure that time-step is set back to positive
2735        !   for this forward step.
2736        !
2737        grid_ptr%dt = abs(grid_ptr%dt)
2738        grid_ptr%time_step = abs(grid_ptr%time_step)
2739        CALL set_current_grid_ptr( grid_ptr )
2740        CALL dfi_fwd_init( grid_ptr )
2741        DO kid = 1, max_nests
2742           IF ( ASSOCIATED( grid_ptr%nests(kid)%ptr ) ) THEN
2743              CALL dfi_fwd_init_recurse(grid_ptr%nests(kid)%ptr)
2744           ENDIF
2745        END DO
2746        grid_ptr => grid_ptr%sibling
2747     END DO
2748     
2749   END SUBROUTINE dfi_fwd_init_recurse
2750
2751!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
2752! DFI forecast initialization group of functions
2753!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
2754
2755   SUBROUTINE wrf_dfi_fst_init ( )
2756
2757     USE module_domain, ONLY : domain, head_grid, domain_get_stop_time, domain_get_start_time, set_current_grid_ptr
2758     USE module_utility
2759     
2760     IMPLICIT NONE
2761
2762     INTERFACE
2763        SUBROUTINE dfi_fst_init_recurse(grid)
2764          USE module_domain, ONLY : domain
2765          TYPE (domain), POINTER :: grid
2766        END SUBROUTINE dfi_fst_init_recurse
2767     END INTERFACE
2768
2769     ! Now, setup all nests
2770
2771     CALL dfi_fst_init_recurse(head_grid)
2772     
2773     CALL set_current_grid_ptr( head_grid )
2774
2775   END SUBROUTINE wrf_dfi_fst_init
2776
2777   RECURSIVE SUBROUTINE dfi_fst_init_recurse ( grid )
2778
2779     USE module_domain, ONLY : domain, domain_get_stop_time, domain_get_start_time, max_nests, set_current_grid_ptr
2780
2781     IMPLICIT NONE
2782
2783      INTERFACE
2784         SUBROUTINE dfi_fst_init(grid)
2785            USE module_domain, ONLY : domain
2786            TYPE (domain), POINTER :: grid
2787         END SUBROUTINE dfi_fst_init
2788      END INTERFACE
2789
2790     INTEGER :: kid
2791     TYPE (domain), POINTER :: grid
2792     TYPE (domain), POINTER :: grid_ptr
2793   
2794     grid_ptr => grid
2795
2796     DO WHILE ( ASSOCIATED( grid_ptr ) )
2797        !
2798        ! Assure that time-step is set back to positive
2799        !   for this forward step.
2800        !
2801        grid_ptr%dt = abs(grid_ptr%dt)
2802        grid_ptr%time_step = abs(grid_ptr%time_step)
2803        CALL set_current_grid_ptr( grid_ptr )
2804        CALL dfi_fst_init( grid_ptr )
2805        DO kid = 1, max_nests
2806           IF ( ASSOCIATED( grid_ptr%nests(kid)%ptr ) ) THEN
2807              CALL dfi_fst_init_recurse(grid_ptr%nests(kid)%ptr)
2808           ENDIF
2809        END DO
2810        grid_ptr => grid_ptr%sibling
2811     END DO
2812     
2813   END SUBROUTINE dfi_fst_init_recurse
2814
2815!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
2816! DFI write initialization group of functions
2817!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
2818
2819   SUBROUTINE wrf_dfi_write_initialized_state( )
2820
2821     USE module_domain, ONLY : domain, head_grid
2822
2823     INTERFACE
2824        SUBROUTINE dfi_write_initialized_state_recurse(grid)
2825          USE module_domain, ONLY : domain
2826          TYPE (domain), POINTER :: grid
2827        END SUBROUTINE dfi_write_initialized_state_recurse
2828     END INTERFACE
2829
2830     ! Now, setup all nests
2831
2832     CALL dfi_write_initialized_state_recurse(head_grid)
2833     
2834   END SUBROUTINE wrf_dfi_write_initialized_state
2835
2836   RECURSIVE SUBROUTINE dfi_write_initialized_state_recurse( grid )
2837
2838     USE module_domain, ONLY : domain, max_nests
2839     
2840     IMPLICIT NONE
2841     
2842     INTERFACE
2843        SUBROUTINE dfi_write_initialized_state( grid )
2844          USE module_domain, ONLY : domain
2845          TYPE (domain), POINTER :: grid
2846        END SUBROUTINE dfi_write_initialized_state
2847     END INTERFACE
2848     
2849     INTEGER :: kid
2850     TYPE (domain), POINTER :: grid
2851     TYPE (domain), POINTER :: grid_ptr
2852     
2853     grid_ptr => grid
2854     
2855     DO WHILE ( ASSOCIATED( grid_ptr ) )
2856        !
2857        ! Assure that time-step is set back to positive
2858        !   for this forward step.
2859        !
2860        CALL dfi_write_initialized_state( grid_ptr )
2861        DO kid = 1, max_nests
2862           IF ( ASSOCIATED( grid_ptr%nests(kid)%ptr ) ) THEN
2863              CALL dfi_write_initialized_state_recurse(grid_ptr%nests(kid)%ptr)
2864           ENDIF
2865        END DO
2866        grid_ptr => grid_ptr%sibling
2867     END DO
2868     
2869   END SUBROUTINE dfi_write_initialized_state_recurse
2870
2871
2872   RECURSIVE SUBROUTINE dfi_array_reset_recurse(grid)
2873
2874     USE module_domain, ONLY : domain, max_nests, set_current_grid_ptr
2875
2876     IMPLICIT NONE
2877
2878      INTERFACE
2879         SUBROUTINE dfi_array_reset(grid)
2880            USE module_domain, ONLY : domain
2881            TYPE (domain), POINTER :: grid
2882         END SUBROUTINE dfi_array_reset
2883      END INTERFACE
2884
2885     INTEGER :: kid
2886     TYPE (domain), POINTER :: grid
2887     TYPE (domain), POINTER :: grid_ptr
2888   
2889     grid_ptr => grid
2890
2891     DO WHILE ( ASSOCIATED( grid_ptr ) )
2892        CALL set_current_grid_ptr( grid_ptr )
2893        CALL dfi_array_reset( grid_ptr )
2894        DO kid = 1, max_nests
2895           IF ( ASSOCIATED( grid_ptr%nests(kid)%ptr ) ) THEN
2896              CALL dfi_array_reset_recurse(grid_ptr%nests(kid)%ptr)
2897           ENDIF
2898        END DO
2899        grid_ptr => grid_ptr%sibling
2900     END DO
2901     
2902   END SUBROUTINE dfi_array_reset_recurse
2903
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