source: LMDZ5/branches/LMDZ5_SPLA/libf/phylmd/hines_gwd.F90 @ 5440

Last change on this file since 5440 was 1992, checked in by lguez, 11 years ago

Converted to free source form files in libf/phylmd which were still in
fixed source form. The conversion was done using the polish mode of
the NAG Fortran Compiler.

In addition to converting to free source form, the processing of the
files also:

-- indented the code (including comments);

-- set Fortran keywords to uppercase, and set all other identifiers
to lower case;

-- added qualifiers to end statements (for example "end subroutine
conflx", instead of "end");

-- changed the terminating statements of all DO loops so that each
loop ends with an ENDDO statement (instead of a labeled continue).

-- replaced #include by include.

  • Property copyright set to
    Name of program: LMDZ
    Creation date: 1984
    Version: LMDZ5
    License: CeCILL version 2
    Holder: Laboratoire de m\'et\'eorologie dynamique, CNRS, UMR 8539
    See the license file in the root directory
  • Property svn:eol-style set to native
  • Property svn:executable set to *
  • Property svn:keywords set to Author Date Id Revision
File size: 62.0 KB
Line 
1
2! $Id: hines_gwd.F90 1992 2014-03-05 13:19:12Z evignon $
3
4SUBROUTINE hines_gwd(nlon, nlev, dtime, paphm1x, papm1x, rlat, tx, ux, vx, &
5    zustrhi, zvstrhi, d_t_hin, d_u_hin, d_v_hin)
6
7  ! ########################################################################
8  ! Parametrization of the momentum flux deposition due to a broad band
9  ! spectrum of gravity waves, following Hines (1997a,b), as coded by
10  ! McLANDRESS (1995). Modified by McFARLANE and MANZINI (1995-1997)
11  ! MAECHAM model stand alone version
12  ! ########################################################################
13
14
15  USE dimphy
16  IMPLICIT NONE
17
18  ! ym#include "dimensions.h"
19  ! ym#include "dimphy.h"
20  include "YOEGWD.h"
21  include "YOMCST.h"
22
23  INTEGER nazmth
24  PARAMETER (nazmth=8)
25
26  ! INPUT ARGUMENTS.
27  ! ----- ----------
28
29  ! - 2D
30  ! PAPHM1   : HALF LEVEL PRESSURE (T-DT)
31  ! PAPM1    : FULL LEVEL PRESSURE (T-DT)
32  ! PTM1     : TEMPERATURE (T-DT)
33  ! PUM1     : ZONAL WIND (T-DT)
34  ! PVM1     : MERIDIONAL WIND (T-DT)
35
36
37  ! REFERENCE.
38  ! ----------
39  ! SEE MODEL DOCUMENTATION
40
41  ! AUTHOR.
42  ! -------
43
44  ! N. MCFARLANE   DKRZ-HAMBURG   MAY 1995
45  ! STAND ALONE E. MANZINI MPI-HAMBURG FEBRUARY 1997
46
47  ! BASED ON A COMBINATION OF THE OROGRAPHIC SCHEME BY N.MCFARLANE 1987
48  ! AND THE HINES SCHEME AS CODED BY C. MCLANDRESS 1995.
49
50
51
52  ! ym      INTEGER KLEVM1
53
54  REAL paphm1(klon, klev+1), papm1(klon, klev)
55  REAL ptm1(klon, klev), pum1(klon, klev), pvm1(klon, klev)
56  REAL prflux(klon)
57  ! 1
58  ! 1
59  ! 1
60  REAL rlat(klon), coslat(klon)
61
62  REAL th(klon, klev), utendgw(klon, klev), vtendgw(klon, klev), &
63    pressg(klon), uhs(klon, klev), vhs(klon, klev), zpr(klon)
64
65  ! * VERTICAL POSITIONING ARRAYS.
66
67  REAL sgj(klon, klev), shj(klon, klev), shxkj(klon, klev), dsgj(klon, klev)
68
69  ! * LOGICAL SWITCHES TO CONTROL ROOF DRAG, ENVELOP GW DRAG AND
70  ! * HINES' DOPPLER SPREADING EXTROWAVE GW DRAG.
71  ! * LOZPR IS TRUE FOR ZPR ENHANCEMENT
72
73
74  ! * WORK ARRAYS.
75
76  REAL m_alpha(klon, klev, nazmth), v_alpha(klon, klev, nazmth), &
77    sigma_alpha(klon, klev, nazmth), sigsqh_alpha(klon, klev, nazmth), &
78    drag_u(klon, klev), drag_v(klon, klev), flux_u(klon, klev), &
79    flux_v(klon, klev), heat(klon, klev), diffco(klon, klev), &
80    bvfreq(klon, klev), density(klon, klev), sigma_t(klon, klev), &
81    visc_mol(klon, klev), alt(klon, klev), sigsqmcw(klon, klev, nazmth), &
82    sigmatm(klon, klev), ak_alpha(klon, nazmth), k_alpha(klon, nazmth), &
83    mmin_alpha(klon, nazmth), i_alpha(klon, nazmth), rmswind(klon), &
84    bvfbot(klon), densbot(klon)
85  REAL smoothr1(klon, klev), smoothr2(klon, klev)
86  REAL sigalpmc(klon, klev, nazmth)
87  REAL f2mod(klon, klev)
88
89  ! * THES ARE THE INPUT PARAMETERS FOR HINES ROUTINE AND
90  ! * ARE SPECIFIED IN ROUTINE HINES_SETUP. SINCE THIS IS CALLED
91  ! * ONLY AT FIRST CALL TO THIS ROUTINE THESE VARIABLES MUST BE SAVED
92  ! * FOR USE AT SUBSEQUENT CALLS. THIS CAN BE AVOIDED BY CALLING
93  ! * HINES_SETUP IN MAIN PROGRAM AND PASSING THE PARAMETERS AS
94  ! * SUBROUTINE ARGUEMENTS.
95
96
97  REAL rmscon
98  INTEGER nmessg, iprint, ilrms
99  INTEGER ifl
100
101  INTEGER naz, icutoff, nsmax, iheatcal
102  REAL slope, f1, f2, f3, f5, f6, kstar(klon), alt_cutoff, smco
103
104  ! PROVIDED AS INPUT
105
106  INTEGER nlon, nlev
107
108  REAL dtime
109  REAL paphm1x(nlon, nlev+1), papm1x(nlon, nlev)
110  REAL ux(nlon, nlev), vx(nlon, nlev), tx(nlon, nlev)
111
112  ! VARIABLES FOR OUTPUT
113
114
115  REAL d_t_hin(nlon, nlev), d_u_hin(nlon, nlev), d_v_hin(nlon, nlev)
116  REAL zustrhi(nlon), zvstrhi(nlon)
117
118
119  ! * LOGICAL SWITCHES TO CONTROL PRECIP ENHANCEMENT AND
120  ! * HINES' DOPPLER SPREADING EXTROWAVE GW DRAG.
121  ! * LOZPR IS TRUE FOR ZPR ENHANCEMENT
122
123  LOGICAL lozpr, lorms(klon)
124
125  ! LOCAL PARAMETERS TO MAKE THINGS WORK (TEMPORARY VARIABLE)
126
127  REAL rhoh2o, zpcons, rgocp, zlat, dttdsf, ratio, hscal
128  INTEGER i, j, l, jl, jk, le, lref, lrefp, levbot
129
130  ! DATA PARAMETERS NEEDED, EXPLAINED LATER
131
132  REAL v0, vmin, dmpscal, taufac, hmin, apibt, cpart, fcrit
133  REAL pcrit, pcons
134  INTEGER iplev, ierror
135
136
137
138  ! PRINT *,' IT IS STARTED HINES GOING ON...'
139
140
141
142
143  ! *    COMPUTATIONAL CONSTANTS.
144  ! ------------- ----------
145
146
147  d_t_hin(:, :) = 0.
148
149  rhoh2o = 1000.
150  zpcons = (1000.*86400.)/rhoh2o
151  ! ym      KLEVM1=KLEV-1
152
153
154  DO jl = kidia, kfdia
155    paphm1(jl, 1) = paphm1x(jl, klev+1)
156    DO jk = 1, klev
157      le = klev + 1 - jk
158      paphm1(jl, jk+1) = paphm1x(jl, le)
159      papm1(jl, jk) = papm1x(jl, le)
160      ptm1(jl, jk) = tx(jl, le)
161      pum1(jl, jk) = ux(jl, le)
162      pvm1(jl, jk) = vx(jl, le)
163    END DO
164  END DO
165
166  ! Define constants and arrays needed for the ccc/mam gwd scheme
167  ! *Constants:
168
169  rgocp = rd/rcpd
170  lrefp = klev - 1
171  lref = klev - 2
172  ! 1
173  ! 1    *Arrays
174  ! 1
175  DO jk = 1, klev
176    DO jl = kidia, kfdia
177      shj(jl, jk) = papm1(jl, jk)/paphm1(jl, klev+1)
178      sgj(jl, jk) = papm1(jl, jk)/paphm1(jl, klev+1)
179      dsgj(jl, jk) = (paphm1(jl,jk+1)-paphm1(jl,jk))/paphm1(jl, klev+1)
180      shxkj(jl, jk) = (papm1(jl,jk)/paphm1(jl,klev+1))**rgocp
181      th(jl, jk) = ptm1(jl, jk)
182    END DO
183  END DO
184
185  ! C
186  DO jl = kidia, kfdia
187    pressg(jl) = paphm1(jl, klev+1)
188  END DO
189
190
191  DO jl = kidia, kfdia
192    prflux(jl) = 0.0
193    zpr(jl) = zpcons*prflux(jl)
194    zlat = (rlat(jl)/180.)*rpi
195    coslat(jl) = cos(zlat)
196  END DO
197
198  ! /#########################################################################
199  ! /
200  ! /
201
202  ! * AUG. 14/95 - C. MCLANDRESS.
203  ! * SEP.    95   N. MCFARLANE.
204
205  ! * THIS ROUTINE CALCULATES THE HORIZONTAL WIND TENDENCIES
206  ! * DUE TO MCFARLANE'S OROGRAPHIC GW DRAG SCHEME, HINES'
207  ! * DOPPLER SPREAD SCHEME FOR "EXTROWAVES" AND ADDS ON
208  ! * ROOF DRAG. IT IS BASED ON THE ROUTINE GWDFLX8.
209
210  ! * LREFP IS THE INDEX OF THE MODEL LEVEL BELOW THE REFERENCE LEVEL
211  ! * I/O ARRAYS PASSED FROM MAIN.
212  ! * (PRESSG = SURFACE PRESSURE)
213
214
215
216
217  ! * CONSTANTS VALUES DEFINED IN DATA STATEMENT ARE :
218  ! * VMIN     = MIMINUM WIND IN THE DIRECTION OF REFERENCE LEVEL
219  ! *            WIND BEFORE WE CONSIDER BREAKING TO HAVE OCCURED.
220  ! * DMPSCAL  = DAMPING TIME FOR GW DRAG IN SECONDS.
221  ! * TAUFAC   = 1/(LENGTH SCALE).
222  ! * HMIN     = MIMINUM ENVELOPE HEIGHT REQUIRED TO PRODUCE GW DRAG.
223  ! * V0       = VALUE OF WIND THAT APPROXIMATES ZERO.
224
225
226  DATA vmin/5.0/, v0/1.E-10/, taufac/5.E-6/, hmin/40000./, dmpscal/6.5E+6/, &
227    apibt/1.5708/, cpart/0.7/, fcrit/1./
228
229  ! * HINES EXTROWAVE GWD CONSTANTS DEFINED IN DATA STATEMENT ARE:
230  ! * RMSCON = ROOT MEAN SQUARE GRAVITY WAVE WIND AT LOWEST LEVEL (M/S).
231  ! * NMESSG  = UNIT NUMBER FOR PRINTED MESSAGES.
232  ! * IPRINT  = 1 TO DO PRINT OUT SOME HINES ARRAYS.
233  ! * IFL     = FIRST CALL FLAG TO HINES_SETUP ("SAVE" IT)
234  ! * PCRIT = CRITICAL VALUE OF ZPR (MM/D)
235  ! * IPLEV = LEVEL OF APPLICATION OF PRCIT
236  ! * PCONS = FACTOR OF ZPR ENHANCEMENT
237
238
239  DATA pcrit/5./, pcons/4.75/
240
241  iplev = lrefp - 1
242
243  DATA rmscon/1.00/iprint/2/, nmessg/6/
244  DATA ifl/0/
245
246  lozpr = .FALSE.
247
248  ! -----------------------------------------------------------------------
249
250
251
252  ! * SET ERROR FLAG
253
254  ierror = 0
255
256  ! * SPECIFY VARIOUS PARAMETERS FOR HINES ROUTINE AT VERY FIRST CALL.
257  ! * (NOTE THAT ARRAY K_ALPHA IS SPECIFIED SO MAKE SURE THAT
258  ! * IT IS NOT OVERWRITTEN LATER ON).
259
260  CALL hines_setup(naz, slope, f1, f2, f3, f5, f6, kstar, icutoff, &
261    alt_cutoff, smco, nsmax, iheatcal, k_alpha, ierror, nmessg, klon, nazmth, &
262    coslat)
263  IF (ierror/=0) GO TO 999
264
265  ! * START GWD CALCULATIONS.
266
267  lref = lrefp - 1
268
269
270  DO j = 1, nazmth
271    DO l = 1, klev
272      DO i = kidia, klon
273        sigsqmcw(i, l, j) = 0.
274      END DO
275    END DO
276  END DO
277
278
279
280  ! * INITIALIZE NECESSARY ARRAYS.
281
282  DO l = 1, klev
283    DO i = kidia, kfdia
284      utendgw(i, l) = 0.
285      vtendgw(i, l) = 0.
286
287      uhs(i, l) = 0.
288      vhs(i, l) = 0.
289
290    END DO
291  END DO
292
293  ! * IF USING HINES SCHEME THEN CALCULATE B V FREQUENCY AT ALL POINTS
294  ! * AND SMOOTH BVFREQ.
295
296  DO l = 2, klev
297    DO i = kidia, kfdia
298      dttdsf = (th(i,l)/shxkj(i,l)-th(i,l-1)/shxkj(i,l-1))/ &
299        (shj(i,l)-shj(i,l-1))
300      dttdsf = min(dttdsf, -5./sgj(i,l))
301      bvfreq(i, l) = sqrt(-dttdsf*sgj(i,l)*(sgj(i,l)**rgocp)/rd)*rg/ptm1(i, l &
302        )
303    END DO
304  END DO
305  DO l = 1, klev
306    DO i = kidia, kfdia
307      IF (l==1) THEN
308        bvfreq(i, l) = bvfreq(i, l+1)
309      END IF
310      IF (l>1) THEN
311        ratio = 5.*log(sgj(i,l)/sgj(i,l-1))
312        bvfreq(i, l) = (bvfreq(i,l-1)+ratio*bvfreq(i,l))/(1.+ratio)
313      END IF
314    END DO
315  END DO
316
317  ! * CALCULATE GW DRAG DUE TO HINES' EXTROWAVES
318  ! * SET MOLECULAR VISCOSITY TO A VERY SMALL VALUE.
319  ! * IF THE MODEL TOP IS GREATER THAN 100 KM THEN THE ACTUAL
320  ! * VISCOSITY COEFFICIENT COULD BE SPECIFIED HERE.
321
322  DO l = 1, klev
323    DO i = kidia, kfdia
324      visc_mol(i, l) = 1.5E-5
325      drag_u(i, l) = 0.
326      drag_v(i, l) = 0.
327      flux_u(i, l) = 0.
328      flux_v(i, l) = 0.
329      heat(i, l) = 0.
330      diffco(i, l) = 0.
331    END DO
332  END DO
333
334  ! * ALTITUDE AND DENSITY AT BOTTOM.
335
336  DO i = kidia, kfdia
337    hscal = rd*ptm1(i, klev)/rg
338    density(i, klev) = sgj(i, klev)*pressg(i)/(rg*hscal)
339    alt(i, klev) = 0.
340  END DO
341
342  ! * ALTITUDE AND DENSITY AT REMAINING LEVELS.
343
344  DO l = klev - 1, 1, -1
345    DO i = kidia, kfdia
346      hscal = rd*ptm1(i, l)/rg
347      alt(i, l) = alt(i, l+1) + hscal*dsgj(i, l)/sgj(i, l)
348      density(i, l) = sgj(i, l)*pressg(i)/(rg*hscal)
349    END DO
350  END DO
351
352
353  ! * INITIALIZE SWITCHES FOR HINES GWD CALCULATION
354
355  ilrms = 0
356
357  DO i = kidia, kfdia
358    lorms(i) = .FALSE.
359  END DO
360
361
362  ! * DEFILE BOTTOM LAUNCH LEVEL
363
364  levbot = iplev
365
366  ! * BACKGROUND WIND MINUS VALUE AT BOTTOM LAUNCH LEVEL.
367
368  DO l = 1, levbot
369    DO i = kidia, kfdia
370      uhs(i, l) = pum1(i, l) - pum1(i, levbot)
371      vhs(i, l) = pvm1(i, l) - pvm1(i, levbot)
372    END DO
373  END DO
374
375  ! * SPECIFY ROOT MEAN SQUARE WIND AT BOTTOM LAUNCH LEVEL.
376
377  DO i = kidia, kfdia
378    rmswind(i) = rmscon
379  END DO
380
381  IF (lozpr) THEN
382    DO i = kidia, kfdia
383      IF (zpr(i)>pcrit) THEN
384        rmswind(i) = rmscon + ((zpr(i)-pcrit)/zpr(i))*pcons
385      END IF
386    END DO
387  END IF
388
389  DO i = kidia, kfdia
390    IF (rmswind(i)>0.0) THEN
391      ilrms = ilrms + 1
392      lorms(i) = .TRUE.
393    END IF
394  END DO
395
396  ! * CALCULATE GWD (NOTE THAT DIFFUSION COEFFICIENT AND
397  ! * HEATING RATE ONLY CALCULATED IF IHEATCAL = 1).
398
399  IF (ilrms>0) THEN
400
401    CALL hines_extro0(drag_u, drag_v, heat, diffco, flux_u, flux_v, uhs, vhs, &
402      bvfreq, density, visc_mol, alt, rmswind, k_alpha, m_alpha, v_alpha, &
403      sigma_alpha, sigsqh_alpha, ak_alpha, mmin_alpha, i_alpha, sigma_t, &
404      densbot, bvfbot, 1, iheatcal, icutoff, iprint, nsmax, smco, alt_cutoff, &
405      kstar, slope, f1, f2, f3, f5, f6, naz, sigsqmcw, sigmatm, kidia, klon, &
406      1, levbot, klon, klev, nazmth, lorms, smoothr1, smoothr2, sigalpmc, &
407      f2mod)
408
409    ! * ADD ON HINES' GWD TENDENCIES TO OROGRAPHIC TENDENCIES AND
410    ! * APPLY HINES' GW DRAG ON (UROW,VROW) WORK ARRAYS.
411
412    DO l = 1, klev
413      DO i = kidia, kfdia
414        utendgw(i, l) = utendgw(i, l) + drag_u(i, l)
415        vtendgw(i, l) = vtendgw(i, l) + drag_v(i, l)
416      END DO
417    END DO
418
419
420    ! * END OF HINES CALCULATIONS.
421
422  END IF
423
424  ! -----------------------------------------------------------------------
425
426  DO jl = kidia, kfdia
427    zustrhi(jl) = flux_u(jl, 1)
428    zvstrhi(jl) = flux_v(jl, 1)
429    DO jk = 1, klev
430      le = klev - jk + 1
431      d_u_hin(jl, jk) = utendgw(jl, le)*dtime
432      d_v_hin(jl, jk) = vtendgw(jl, le)*dtime
433    END DO
434  END DO
435
436  ! PRINT *,'UTENDGW:',UTENDGW
437
438  ! PRINT *,' HINES HAS BEEN COMPLETED (LONG ISNT IT...)'
439
440  RETURN
441999 CONTINUE
442
443  ! * IF ERROR DETECTED THEN ABORT.
444
445  WRITE (nmessg, 6000)
446  WRITE (nmessg, 6010) ierror
4476000 FORMAT (/' EXECUTION ABORTED IN GWDOREXV')
4486010 FORMAT ('     ERROR FLAG =', I4)
449
450
451  RETURN
452END SUBROUTINE hines_gwd
453! /
454! /
455
456
457SUBROUTINE hines_extro0(drag_u, drag_v, heat, diffco, flux_u, flux_v, vel_u, &
458    vel_v, bvfreq, density, visc_mol, alt, rmswind, k_alpha, m_alpha, &
459    v_alpha, sigma_alpha, sigsqh_alpha, ak_alpha, mmin_alpha, i_alpha, &
460    sigma_t, densb, bvfb, iorder, iheatcal, icutoff, iprint, nsmax, smco, &
461    alt_cutoff, kstar, slope, f1, f2, f3, f5, f6, naz, sigsqmcw, sigmatm, &
462    il1, il2, lev1, lev2, nlons, nlevs, nazmth, lorms, smoothr1, smoothr2, &
463    sigalpmc, f2mod)
464
465  IMPLICIT NONE
466
467  ! Main routine for Hines' "extrowave" gravity wave parameterization based
468  ! on Hines' Doppler spread theory. This routine calculates zonal
469  ! and meridional components of gravity wave drag, heating rates
470  ! and diffusion coefficient on a longitude by altitude grid.
471  ! No "mythical" lower boundary region calculation is made so it
472  ! is assumed that lowest level winds are weak (i.e, approximately zero).
473
474  ! Aug. 13/95 - C. McLandress
475  ! SEPT. /95  - N.McFarlane
476
477  ! Modifications:
478
479  ! Output arguements:
480
481  ! * DRAG_U = zonal component of gravity wave drag (m/s^2).
482  ! * DRAG_V = meridional component of gravity wave drag (m/s^2).
483  ! * HEAT   = gravity wave heating (K/sec).
484  ! * DIFFCO = diffusion coefficient (m^2/sec)
485  ! * FLUX_U = zonal component of vertical momentum flux (Pascals)
486  ! * FLUX_V = meridional component of vertical momentum flux (Pascals)
487
488  ! Input arguements:
489
490  ! * VEL_U      = background zonal wind component (m/s).
491  ! * VEL_V      = background meridional wind component (m/s).
492  ! * BVFREQ     = background Brunt Vassala frequency (radians/sec).
493  ! * DENSITY    = background density (kg/m^3)
494  ! * VISC_MOL   = molecular viscosity (m^2/s)
495  ! * ALT        = altitude of momentum, density, buoyancy levels (m)
496  ! *              (NOTE: levels ordered so that ALT(I,1) > ALT(I,2), etc.)
497  ! * RMSWIND   = root mean square gravity wave wind at lowest level (m/s).
498  ! * K_ALPHA    = horizontal wavenumber of each azimuth (1/m).
499  ! * IORDER       = 1 means vertical levels are indexed from top down
500  ! *              (i.e., highest level indexed 1 and lowest level NLEVS);
501  ! *           .NE. 1 highest level is index NLEVS.
502  ! * IHEATCAL   = 1 to calculate heating rates and diffusion coefficient.
503  ! * IPRINT     = 1 to print out various arrays.
504  ! * ICUTOFF    = 1 to exponentially damp GWD, heating and diffusion
505  ! *              arrays above ALT_CUTOFF; otherwise arrays not modified.
506  ! * ALT_CUTOFF = altitude in meters above which exponential decay applied.
507  ! * SMCO       = smoothing factor used to smooth cutoff vertical
508  ! *              wavenumbers and total rms winds in vertical direction
509  ! *              before calculating drag or heating
510  ! *              (SMCO >= 1 ==> 1:SMCO:1 stencil used).
511  ! * NSMAX      = number of times smoother applied ( >= 1),
512  ! *            = 0 means no smoothing performed.
513  ! * KSTAR      = typical gravity wave horizontal wavenumber (1/m).
514  ! * SLOPE      = slope of incident vertical wavenumber spectrum
515  ! *              (SLOPE must equal 1., 1.5 or 2.).
516  ! * F1 to F6   = Hines's fudge factors (F4 not needed since used for
517  ! *              vertical flux of vertical momentum).
518  ! * NAZ        = actual number of horizontal azimuths used.
519  ! * IL1        = first longitudinal index to use (IL1 >= 1).
520  ! * IL2        = last longitudinal index to use (IL1 <= IL2 <= NLONS).
521  ! * LEV1       = index of first level for drag calculation.
522  ! * LEV2       = index of last level for drag calculation
523  ! *              (i.e., LEV1 < LEV2 <= NLEVS).
524  ! * NLONS      = number of longitudes.
525  ! * NLEVS      = number of vertical levels.
526  ! * NAZMTH     = azimuthal array dimension (NAZMTH >= NAZ).
527
528  ! Work arrays.
529
530  ! * M_ALPHA      = cutoff vertical wavenumber (1/m).
531  ! * V_ALPHA      = wind component at each azimuth (m/s) and if IHEATCAL=1
532  ! *                holds vertical derivative of cutoff wavenumber.
533  ! * SIGMA_ALPHA  = total rms wind in each azimuth (m/s).
534  ! * SIGSQH_ALPHA = portion of wind variance from waves having wave
535  ! *                normals in the alpha azimuth (m/s).
536  ! * SIGMA_T      = total rms horizontal wind (m/s).
537  ! * AK_ALPHA     = spectral amplitude factor at each azimuth
538  ! *                (i.e.,{AjKj}) in m^4/s^2.
539  ! * I_ALPHA      = Hines' integral.
540  ! * MMIN_ALPHA   = minimum value of cutoff wavenumber.
541  ! * DENSB        = background density at bottom level.
542  ! * BVFB         = buoyancy frequency at bottom level and
543  ! *                work array for ICUTOFF = 1.
544
545  ! * LORMS       = .TRUE. for drag computation
546
547  INTEGER naz, nlons, nlevs, nazmth, il1, il2, lev1, lev2
548  INTEGER icutoff, nsmax, iorder, iheatcal, iprint
549  REAL kstar(nlons), f1, f2, f3, f5, f6, slope
550  REAL alt_cutoff, smco
551  REAL drag_u(nlons, nlevs), drag_v(nlons, nlevs)
552  REAL heat(nlons, nlevs), diffco(nlons, nlevs)
553  REAL flux_u(nlons, nlevs), flux_v(nlons, nlevs)
554  REAL vel_u(nlons, nlevs), vel_v(nlons, nlevs)
555  REAL bvfreq(nlons, nlevs), density(nlons, nlevs)
556  REAL visc_mol(nlons, nlevs), alt(nlons, nlevs)
557  REAL rmswind(nlons), bvfb(nlons), densb(nlons)
558  REAL sigma_t(nlons, nlevs), sigsqmcw(nlons, nlevs, nazmth)
559  REAL sigma_alpha(nlons, nlevs, nazmth), sigmatm(nlons, nlevs)
560  REAL sigsqh_alpha(nlons, nlevs, nazmth)
561  REAL m_alpha(nlons, nlevs, nazmth), v_alpha(nlons, nlevs, nazmth)
562  REAL ak_alpha(nlons, nazmth), k_alpha(nlons, nazmth)
563  REAL mmin_alpha(nlons, nazmth), i_alpha(nlons, nazmth)
564  REAL smoothr1(nlons, nlevs), smoothr2(nlons, nlevs)
565  REAL sigalpmc(nlons, nlevs, nazmth)
566  REAL f2mod(nlons, nlevs)
567
568  LOGICAL lorms(nlons)
569
570  ! Internal variables.
571
572  INTEGER levbot, levtop, i, n, l, lev1p, lev2m
573  INTEGER ilprt1, ilprt2
574  ! -----------------------------------------------------------------------
575
576  ! PRINT *,' IN HINES_EXTRO0'
577  lev1p = lev1 + 1
578  lev2m = lev2 - 1
579
580  ! Index of lowest altitude level (bottom of drag calculation).
581
582  levbot = lev2
583  levtop = lev1
584  IF (iorder/=1) THEN
585    WRITE (6, 1)
5861   FORMAT (2X, ' error: IORDER NOT ONE! ')
587  END IF
588
589  ! Buoyancy and density at bottom level.
590
591  DO i = il1, il2
592    bvfb(i) = bvfreq(i, levbot)
593    densb(i) = density(i, levbot)
594  END DO
595
596  ! initialize some variables
597
598  DO n = 1, naz
599    DO l = lev1, lev2
600      DO i = il1, il2
601        m_alpha(i, l, n) = 0.0
602      END DO
603    END DO
604  END DO
605  DO l = lev1, lev2
606    DO i = il1, il2
607      sigma_t(i, l) = 0.0
608    END DO
609  END DO
610  DO n = 1, naz
611    DO i = il1, il2
612      i_alpha(i, n) = 0.0
613    END DO
614  END DO
615
616  ! Compute azimuthal wind components from zonal and meridional winds.
617
618  CALL hines_wind(v_alpha, vel_u, vel_v, naz, il1, il2, lev1, lev2, nlons, &
619    nlevs, nazmth)
620
621  ! Calculate cutoff vertical wavenumber and velocity variances.
622
623  CALL hines_wavnum(m_alpha, sigma_alpha, sigsqh_alpha, sigma_t, ak_alpha, &
624    v_alpha, visc_mol, density, densb, bvfreq, bvfb, rmswind, i_alpha, &
625    mmin_alpha, kstar, slope, f1, f2, f3, naz, levbot, levtop, il1, il2, &
626    nlons, nlevs, nazmth, sigsqmcw, sigmatm, lorms, sigalpmc, f2mod)
627
628  ! Smooth cutoff wavenumbers and total rms velocity in the vertical
629  ! direction NSMAX times, using FLUX_U as temporary work array.
630
631  IF (nsmax>0) THEN
632    DO n = 1, naz
633      DO l = lev1, lev2
634        DO i = il1, il2
635          smoothr1(i, l) = m_alpha(i, l, n)
636        END DO
637      END DO
638      CALL vert_smooth(smoothr1, smoothr2, smco, nsmax, il1, il2, lev1, lev2, &
639        nlons, nlevs)
640      DO l = lev1, lev2
641        DO i = il1, il2
642          m_alpha(i, l, n) = smoothr1(i, l)
643        END DO
644      END DO
645    END DO
646    CALL vert_smooth(sigma_t, smoothr2, smco, nsmax, il1, il2, lev1, lev2, &
647      nlons, nlevs)
648  END IF
649
650  ! Calculate zonal and meridional components of the
651  ! momentum flux and drag.
652
653  CALL hines_flux(flux_u, flux_v, drag_u, drag_v, alt, density, densb, &
654    m_alpha, ak_alpha, k_alpha, slope, naz, il1, il2, lev1, lev2, nlons, &
655    nlevs, nazmth, lorms)
656
657  ! Cutoff drag above ALT_CUTOFF, using BVFB as temporary work array.
658
659  IF (icutoff==1) THEN
660    CALL hines_exp(drag_u, bvfb, alt, alt_cutoff, iorder, il1, il2, lev1, &
661      lev2, nlons, nlevs)
662    CALL hines_exp(drag_v, bvfb, alt, alt_cutoff, iorder, il1, il2, lev1, &
663      lev2, nlons, nlevs)
664  END IF
665
666  ! Print out various arrays for diagnostic purposes.
667
668  IF (iprint==1) THEN
669    ilprt1 = 15
670    ilprt2 = 16
671    CALL hines_print(flux_u, flux_v, drag_u, drag_v, alt, sigma_t, &
672      sigma_alpha, v_alpha, m_alpha, 1, 1, 6, ilprt1, ilprt2, lev1, lev2, &
673      naz, nlons, nlevs, nazmth)
674  END IF
675
676  ! If not calculating heating rate and diffusion coefficient then finished.
677
678  IF (iheatcal/=1) RETURN
679
680  ! Calculate vertical derivative of cutoff wavenumber (store
681  ! in array V_ALPHA) using centered differences at interior gridpoints
682  ! and one-sided differences at first and last levels.
683
684  DO n = 1, naz
685    DO l = lev1p, lev2m
686      DO i = il1, il2
687        v_alpha(i, l, n) = (m_alpha(i,l+1,n)-m_alpha(i,l-1,n))/ &
688          (alt(i,l+1)-alt(i,l-1))
689      END DO
690    END DO
691    DO i = il1, il2
692      v_alpha(i, lev1, n) = (m_alpha(i,lev1p,n)-m_alpha(i,lev1,n))/ &
693        (alt(i,lev1p)-alt(i,lev1))
694    END DO
695    DO i = il1, il2
696      v_alpha(i, lev2, n) = (m_alpha(i,lev2,n)-m_alpha(i,lev2m,n))/ &
697        (alt(i,lev2)-alt(i,lev2m))
698    END DO
699  END DO
700
701  ! Heating rate and diffusion coefficient.
702
703  CALL hines_heat(heat, diffco, m_alpha, v_alpha, ak_alpha, k_alpha, bvfreq, &
704    density, densb, sigma_t, visc_mol, kstar, slope, f2, f3, f5, f6, naz, &
705    il1, il2, lev1, lev2, nlons, nlevs, nazmth)
706
707  ! Finished.
708
709  RETURN
710  ! -----------------------------------------------------------------------
711END SUBROUTINE hines_extro0
712
713SUBROUTINE hines_wavnum(m_alpha, sigma_alpha, sigsqh_alpha, sigma_t, &
714    ak_alpha, v_alpha, visc_mol, density, densb, bvfreq, bvfb, rms_wind, &
715    i_alpha, mmin_alpha, kstar, slope, f1, f2, f3, naz, levbot, levtop, il1, &
716    il2, nlons, nlevs, nazmth, sigsqmcw, sigmatm, lorms, sigalpmc, f2mod)
717
718  ! This routine calculates the cutoff vertical wavenumber and velocity
719  ! variances on a longitude by altitude grid for the Hines' Doppler
720  ! spread gravity wave drag parameterization scheme.
721  ! NOTE: (1) only values of four or eight can be used for # azimuths (NAZ).
722  ! (2) only values of 1.0, 1.5 or 2.0 can be used for slope (SLOPE).
723
724  ! Aug. 10/95 - C. McLandress
725
726  ! Output arguements:
727
728  ! * M_ALPHA      = cutoff wavenumber at each azimuth (1/m).
729  ! * SIGMA_ALPHA  = total rms wind in each azimuth (m/s).
730  ! * SIGSQH_ALPHA = portion of wind variance from waves having wave
731  ! *                normals in the alpha azimuth (m/s).
732  ! * SIGMA_T      = total rms horizontal wind (m/s).
733  ! * AK_ALPHA     = spectral amplitude factor at each azimuth
734  ! *                (i.e.,{AjKj}) in m^4/s^2.
735
736  ! Input arguements:
737
738  ! * V_ALPHA  = wind component at each azimuth (m/s).
739  ! * VISC_MOL = molecular viscosity (m^2/s)
740  ! * DENSITY  = background density (kg/m^3).
741  ! * DENSB    = background density at model bottom (kg/m^3).
742  ! * BVFREQ   = background Brunt Vassala frequency (radians/sec).
743  ! * BVFB     = background Brunt Vassala frequency at model bottom.
744  ! * RMS_WIND = root mean square gravity wave wind at lowest level (m/s).
745  ! * KSTAR    = typical gravity wave horizontal wavenumber (1/m).
746  ! * SLOPE    = slope of incident vertical wavenumber spectrum
747  ! *            (SLOPE = 1., 1.5 or 2.).
748  ! * F1,F2,F3 = Hines's fudge factors.
749  ! * NAZ      = actual number of horizontal azimuths used (4 or 8).
750  ! * LEVBOT   = index of lowest vertical level.
751  ! * LEVTOP   = index of highest vertical level
752  ! *            (NOTE: if LEVTOP < LEVBOT then level index
753  ! *             increases from top down).
754  ! * IL1      = first longitudinal index to use (IL1 >= 1).
755  ! * IL2      = last longitudinal index to use (IL1 <= IL2 <= NLONS).
756  ! * NLONS    = number of longitudes.
757  ! * NLEVS    = number of vertical levels.
758  ! * NAZMTH   = azimuthal array dimension (NAZMTH >= NAZ).
759
760  ! * LORMS       = .TRUE. for drag computation
761
762  ! Input work arrays:
763
764  ! * I_ALPHA    = Hines' integral at a single level.
765  ! * MMIN_ALPHA = minimum value of cutoff wavenumber.
766
767  INTEGER naz, levbot, levtop, il1, il2, nlons, nlevs, nazmth
768  REAL slope, kstar(nlons), f1, f2, f3
769  REAL m_alpha(nlons, nlevs, nazmth)
770  REAL sigma_alpha(nlons, nlevs, nazmth)
771  REAL sigalpmc(nlons, nlevs, nazmth)
772  REAL sigsqh_alpha(nlons, nlevs, nazmth)
773  REAL sigsqmcw(nlons, nlevs, nazmth)
774  REAL sigma_t(nlons, nlevs)
775  REAL sigmatm(nlons, nlevs)
776  REAL ak_alpha(nlons, nazmth)
777  REAL v_alpha(nlons, nlevs, nazmth)
778  REAL visc_mol(nlons, nlevs)
779  REAL f2mod(nlons, nlevs)
780  REAL density(nlons, nlevs), densb(nlons)
781  REAL bvfreq(nlons, nlevs), bvfb(nlons), rms_wind(nlons)
782  REAL i_alpha(nlons, nazmth), mmin_alpha(nlons, nazmth)
783
784  LOGICAL lorms(nlons)
785
786  ! Internal variables.
787
788  INTEGER i, l, n, lstart, lend, lincr, lbelow
789  REAL m_sub_m_turb, m_sub_m_mol, m_trial
790  REAL visc, visc_min, azfac, sp1
791
792  ! c      REAL  N_OVER_M(1000), SIGFAC(1000)
793
794  REAL n_over_m(nlons), sigfac(nlons)
795  DATA visc_min/1.E-10/
796  ! -----------------------------------------------------------------------
797
798
799  ! PRINT *,'IN HINES_WAVNUM'
800  sp1 = slope + 1.
801
802  ! Indices of levels to process.
803
804  IF (levbot>levtop) THEN
805    lstart = levbot - 1
806    lend = levtop
807    lincr = -1
808  ELSE
809    WRITE (6, 1)
8101   FORMAT (2X, ' error: IORDER NOT ONE! ')
811  END IF
812
813  ! Use horizontal isotropy to calculate azimuthal variances at bottom level.
814
815  azfac = 1./real(naz)
816  DO n = 1, naz
817    DO i = il1, il2
818      sigsqh_alpha(i, levbot, n) = azfac*rms_wind(i)**2
819    END DO
820  END DO
821
822  ! Velocity variances at bottom level.
823
824  CALL hines_sigma(sigma_t, sigma_alpha, sigsqh_alpha, naz, levbot, il1, il2, &
825    nlons, nlevs, nazmth)
826
827  CALL hines_sigma(sigmatm, sigalpmc, sigsqmcw, naz, levbot, il1, il2, nlons, &
828    nlevs, nazmth)
829
830  ! Calculate cutoff wavenumber and spectral amplitude factor
831  ! at bottom level where it is assumed that background winds vanish
832  ! and also initialize minimum value of cutoff wavnumber.
833
834  DO n = 1, naz
835    DO i = il1, il2
836      IF (lorms(i)) THEN
837        m_alpha(i, levbot, n) = bvfb(i)/(f1*sigma_alpha(i,levbot,n)+f2* &
838          sigma_t(i,levbot))
839        ak_alpha(i, n) = sigsqh_alpha(i, levbot, n)/ &
840          (m_alpha(i,levbot,n)**sp1/sp1)
841        mmin_alpha(i, n) = m_alpha(i, levbot, n)
842      END IF
843    END DO
844  END DO
845
846  ! Calculate quantities from the bottom upwards,
847  ! starting one level above bottom.
848
849  DO l = lstart, lend, lincr
850
851    ! Level beneath present level.
852
853    lbelow = l - lincr
854
855    ! Calculate N/m_M where m_M is maximum permissible value of the vertical
856    ! wavenumber (i.e., m > m_M are obliterated) and N is buoyancy frequency.
857    ! m_M is taken as the smaller of the instability-induced
858    ! wavenumber (M_SUB_M_TURB) and that imposed by molecular viscosity
859    ! (M_SUB_M_MOL). Since variance at this level is not yet known
860    ! use value at level below.
861
862    DO i = il1, il2
863      IF (lorms(i)) THEN
864
865        f2mfac = sigmatm(i, lbelow)**2
866        f2mod(i, lbelow) = 1. + 2.*f2mfac/(f2mfac+sigma_t(i,lbelow)**2)
867
868        visc = amax1(visc_mol(i,l), visc_min)
869        m_sub_m_turb = bvfreq(i, l)/(f2*f2mod(i,lbelow)*sigma_t(i,lbelow))
870        m_sub_m_mol = (bvfreq(i,l)*kstar(i)/visc)**0.33333333/f3
871        IF (m_sub_m_turb<m_sub_m_mol) THEN
872          n_over_m(i) = f2*f2mod(i, lbelow)*sigma_t(i, lbelow)
873        ELSE
874          n_over_m(i) = bvfreq(i, l)/m_sub_m_mol
875        END IF
876      END IF
877    END DO
878
879    ! Calculate cutoff wavenumber at this level.
880
881    DO n = 1, naz
882      DO i = il1, il2
883        IF (lorms(i)) THEN
884
885          ! Calculate trial value (since variance at this level is not yet
886          ! known
887          ! use value at level below). If trial value is negative or if it
888          ! exceeds
889          ! minimum value (not permitted) then set it to minimum value.
890
891          m_trial = bvfb(i)/(f1*(sigma_alpha(i,lbelow,n)+sigalpmc(i,lbelow, &
892            n))+n_over_m(i)+v_alpha(i,l,n))
893          IF (m_trial<=0. .OR. m_trial>mmin_alpha(i,n)) THEN
894            m_trial = mmin_alpha(i, n)
895          END IF
896          m_alpha(i, l, n) = m_trial
897
898          ! Reset minimum value of cutoff wavenumber if necessary.
899
900          IF (m_alpha(i,l,n)<mmin_alpha(i,n)) THEN
901            mmin_alpha(i, n) = m_alpha(i, l, n)
902          END IF
903
904        END IF
905      END DO
906    END DO
907
908    ! Calculate the Hines integral at this level.
909
910    CALL hines_intgrl(i_alpha, v_alpha, m_alpha, bvfb, slope, naz, l, il1, &
911      il2, nlons, nlevs, nazmth, lorms)
912
913
914    ! Calculate the velocity variances at this level.
915
916    DO i = il1, il2
917      sigfac(i) = densb(i)/density(i, l)*bvfreq(i, l)/bvfb(i)
918    END DO
919    DO n = 1, naz
920      DO i = il1, il2
921        sigsqh_alpha(i, l, n) = sigfac(i)*ak_alpha(i, n)*i_alpha(i, n)
922      END DO
923    END DO
924    CALL hines_sigma(sigma_t, sigma_alpha, sigsqh_alpha, naz, l, il1, il2, &
925      nlons, nlevs, nazmth)
926
927    CALL hines_sigma(sigmatm, sigalpmc, sigsqmcw, naz, l, il1, il2, nlons, &
928      nlevs, nazmth)
929
930    ! End of level loop.
931
932  END DO
933
934  RETURN
935  ! -----------------------------------------------------------------------
936END SUBROUTINE hines_wavnum
937
938SUBROUTINE hines_wind(v_alpha, vel_u, vel_v, naz, il1, il2, lev1, lev2, &
939    nlons, nlevs, nazmth)
940
941  ! This routine calculates the azimuthal horizontal background wind
942  ! components
943  ! on a longitude by altitude grid for the case of 4 or 8 azimuths for
944  ! the Hines' Doppler spread GWD parameterization scheme.
945
946  ! Aug. 7/95 - C. McLandress
947
948  ! Output arguement:
949
950  ! * V_ALPHA   = background wind component at each azimuth (m/s).
951  ! *             (note: first azimuth is in eastward direction
952  ! *              and rotate in counterclockwise direction.)
953
954  ! Input arguements:
955
956  ! * VEL_U     = background zonal wind component (m/s).
957  ! * VEL_V     = background meridional wind component (m/s).
958  ! * NAZ       = actual number of horizontal azimuths used (must be 4 or 8).
959  ! * IL1       = first longitudinal index to use (IL1 >= 1).
960  ! * IL2       = last longitudinal index to use (IL1 <= IL2 <= NLONS).
961  ! * LEV1      = first altitude level to use (LEV1 >=1).
962  ! * LEV2      = last altitude level to use (LEV1 < LEV2 <= NLEVS).
963  ! * NLONS     = number of longitudes.
964  ! * NLEVS     = number of vertical levels.
965  ! * NAZMTH    = azimuthal array dimension (NAZMTH >= NAZ).
966
967  ! Constants in DATA statements.
968
969  ! * COS45 = cosine of 45 degrees.
970  ! * UMIN  = minimum allowable value for zonal or meridional
971  ! *         wind component (m/s).
972
973  ! Subroutine arguements.
974
975  INTEGER naz, il1, il2, lev1, lev2
976  INTEGER nlons, nlevs, nazmth
977  REAL v_alpha(nlons, nlevs, nazmth)
978  REAL vel_u(nlons, nlevs), vel_v(nlons, nlevs)
979
980  ! Internal variables.
981
982  INTEGER i, l
983  REAL u, v, cos45, umin
984
985  DATA cos45/0.7071068/
986  DATA umin/0.001/
987  ! -----------------------------------------------------------------------
988
989  ! Case with 4 azimuths.
990
991
992  ! PRINT *,'IN HINES_WIND'
993  IF (naz==4) THEN
994    DO l = lev1, lev2
995      DO i = il1, il2
996        u = vel_u(i, l)
997        v = vel_v(i, l)
998        IF (abs(u)<umin) u = umin
999        IF (abs(v)<umin) v = umin
1000        v_alpha(i, l, 1) = u
1001        v_alpha(i, l, 2) = v
1002        v_alpha(i, l, 3) = -u
1003        v_alpha(i, l, 4) = -v
1004      END DO
1005    END DO
1006  END IF
1007
1008  ! Case with 8 azimuths.
1009
1010  IF (naz==8) THEN
1011    DO l = lev1, lev2
1012      DO i = il1, il2
1013        u = vel_u(i, l)
1014        v = vel_v(i, l)
1015        IF (abs(u)<umin) u = umin
1016        IF (abs(v)<umin) v = umin
1017        v_alpha(i, l, 1) = u
1018        v_alpha(i, l, 2) = cos45*(v+u)
1019        v_alpha(i, l, 3) = v
1020        v_alpha(i, l, 4) = cos45*(v-u)
1021        v_alpha(i, l, 5) = -u
1022        v_alpha(i, l, 6) = -v_alpha(i, l, 2)
1023        v_alpha(i, l, 7) = -v
1024        v_alpha(i, l, 8) = -v_alpha(i, l, 4)
1025      END DO
1026    END DO
1027  END IF
1028
1029  RETURN
1030  ! -----------------------------------------------------------------------
1031END SUBROUTINE hines_wind
1032
1033SUBROUTINE hines_flux(flux_u, flux_v, drag_u, drag_v, alt, density, densb, &
1034    m_alpha, ak_alpha, k_alpha, slope, naz, il1, il2, lev1, lev2, nlons, &
1035    nlevs, nazmth, lorms)
1036
1037  ! Calculate zonal and meridional components of the vertical flux
1038  ! of horizontal momentum and corresponding wave drag (force per unit mass)
1039  ! on a longitude by altitude grid for the Hines' Doppler spread
1040  ! GWD parameterization scheme.
1041  ! NOTE: only 4 or 8 azimuths can be used.
1042
1043  ! Aug. 6/95 - C. McLandress
1044
1045  ! Output arguements:
1046
1047  ! * FLUX_U = zonal component of vertical momentum flux (Pascals)
1048  ! * FLUX_V = meridional component of vertical momentum flux (Pascals)
1049  ! * DRAG_U = zonal component of drag (m/s^2).
1050  ! * DRAG_V = meridional component of drag (m/s^2).
1051
1052  ! Input arguements:
1053
1054  ! * ALT       = altitudes (m).
1055  ! * DENSITY   = background density (kg/m^3).
1056  ! * DENSB     = background density at bottom level (kg/m^3).
1057  ! * M_ALPHA   = cutoff vertical wavenumber (1/m).
1058  ! * AK_ALPHA  = spectral amplitude factor (i.e., {AjKj} in m^4/s^2).
1059  ! * K_ALPHA   = horizontal wavenumber (1/m).
1060  ! * SLOPE     = slope of incident vertical wavenumber spectrum.
1061  ! * NAZ       = actual number of horizontal azimuths used (must be 4 or 8).
1062  ! * IL1       = first longitudinal index to use (IL1 >= 1).
1063  ! * IL2       = last longitudinal index to use (IL1 <= IL2 <= NLONS).
1064  ! * LEV1      = first altitude level to use (LEV1 >=1).
1065  ! * LEV2      = last altitude level to use (LEV1 < LEV2 <= NLEVS).
1066  ! * NLONS     = number of longitudes.
1067  ! * NLEVS     = number of vertical levels.
1068  ! * NAZMTH    = azimuthal array dimension (NAZMTH >= NAZ).
1069
1070  ! * LORMS       = .TRUE. for drag computation
1071
1072  ! Constant in DATA statement.
1073
1074  ! * COS45 = cosine of 45 degrees.
1075
1076  ! Subroutine arguements.
1077
1078  INTEGER naz, il1, il2, lev1, lev2
1079  INTEGER nlons, nlevs, nazmth
1080  REAL slope
1081  REAL flux_u(nlons, nlevs), flux_v(nlons, nlevs)
1082  REAL drag_u(nlons, nlevs), drag_v(nlons, nlevs)
1083  REAL alt(nlons, nlevs), density(nlons, nlevs), densb(nlons)
1084  REAL m_alpha(nlons, nlevs, nazmth)
1085  REAL ak_alpha(nlons, nazmth), k_alpha(nlons, nazmth)
1086
1087  LOGICAL lorms(nlons)
1088
1089  ! Internal variables.
1090
1091  INTEGER i, l, lev1p, lev2m
1092  REAL cos45, prod2, prod4, prod6, prod8, dendz, dendz2
1093  DATA cos45/0.7071068/
1094  ! -----------------------------------------------------------------------
1095
1096  lev1p = lev1 + 1
1097  lev2m = lev2 - 1
1098  lev2p = lev2 + 1
1099
1100  ! Sum over azimuths for case where SLOPE = 1.
1101
1102  IF (slope==1.) THEN
1103
1104    ! Case with 4 azimuths.
1105
1106    IF (naz==4) THEN
1107      DO l = lev1, lev2
1108        DO i = il1, il2
1109          flux_u(i, l) = ak_alpha(i, 1)*k_alpha(i, 1)*m_alpha(i, l, 1) - &
1110            ak_alpha(i, 3)*k_alpha(i, 3)*m_alpha(i, l, 3)
1111          flux_v(i, l) = ak_alpha(i, 2)*k_alpha(i, 2)*m_alpha(i, l, 2) - &
1112            ak_alpha(i, 4)*k_alpha(i, 4)*m_alpha(i, l, 4)
1113        END DO
1114      END DO
1115    END IF
1116
1117    ! Case with 8 azimuths.
1118
1119    IF (naz==8) THEN
1120      DO l = lev1, lev2
1121        DO i = il1, il2
1122          prod2 = ak_alpha(i, 2)*k_alpha(i, 2)*m_alpha(i, l, 2)
1123          prod4 = ak_alpha(i, 4)*k_alpha(i, 4)*m_alpha(i, l, 4)
1124          prod6 = ak_alpha(i, 6)*k_alpha(i, 6)*m_alpha(i, l, 6)
1125          prod8 = ak_alpha(i, 8)*k_alpha(i, 8)*m_alpha(i, l, 8)
1126          flux_u(i, l) = ak_alpha(i, 1)*k_alpha(i, 1)*m_alpha(i, l, 1) - &
1127            ak_alpha(i, 5)*k_alpha(i, 5)*m_alpha(i, l, 5) + &
1128            cos45*(prod2-prod4-prod6+prod8)
1129          flux_v(i, l) = ak_alpha(i, 3)*k_alpha(i, 3)*m_alpha(i, l, 3) - &
1130            ak_alpha(i, 7)*k_alpha(i, 7)*m_alpha(i, l, 7) + &
1131            cos45*(prod2+prod4-prod6-prod8)
1132        END DO
1133      END DO
1134    END IF
1135
1136  END IF
1137
1138  ! Sum over azimuths for case where SLOPE not equal to 1.
1139
1140  IF (slope/=1.) THEN
1141
1142    ! Case with 4 azimuths.
1143
1144    IF (naz==4) THEN
1145      DO l = lev1, lev2
1146        DO i = il1, il2
1147          flux_u(i, l) = ak_alpha(i, 1)*k_alpha(i, 1)* &
1148            m_alpha(i, l, 1)**slope - ak_alpha(i, 3)*k_alpha(i, 3)*m_alpha(i, &
1149            l, 3)**slope
1150          flux_v(i, l) = ak_alpha(i, 2)*k_alpha(i, 2)* &
1151            m_alpha(i, l, 2)**slope - ak_alpha(i, 4)*k_alpha(i, 4)*m_alpha(i, &
1152            l, 4)**slope
1153        END DO
1154      END DO
1155    END IF
1156
1157    ! Case with 8 azimuths.
1158
1159    IF (naz==8) THEN
1160      DO l = lev1, lev2
1161        DO i = il1, il2
1162          prod2 = ak_alpha(i, 2)*k_alpha(i, 2)*m_alpha(i, l, 2)**slope
1163          prod4 = ak_alpha(i, 4)*k_alpha(i, 4)*m_alpha(i, l, 4)**slope
1164          prod6 = ak_alpha(i, 6)*k_alpha(i, 6)*m_alpha(i, l, 6)**slope
1165          prod8 = ak_alpha(i, 8)*k_alpha(i, 8)*m_alpha(i, l, 8)**slope
1166          flux_u(i, l) = ak_alpha(i, 1)*k_alpha(i, 1)* &
1167            m_alpha(i, l, 1)**slope - ak_alpha(i, 5)*k_alpha(i, 5)*m_alpha(i, &
1168            l, 5)**slope + cos45*(prod2-prod4-prod6+prod8)
1169          flux_v(i, l) = ak_alpha(i, 3)*k_alpha(i, 3)* &
1170            m_alpha(i, l, 3)**slope - ak_alpha(i, 7)*k_alpha(i, 7)*m_alpha(i, &
1171            l, 7)**slope + cos45*(prod2+prod4-prod6-prod8)
1172        END DO
1173      END DO
1174    END IF
1175
1176  END IF
1177
1178  ! Calculate flux from sum.
1179
1180  DO l = lev1, lev2
1181    DO i = il1, il2
1182      flux_u(i, l) = flux_u(i, l)*densb(i)/slope
1183      flux_v(i, l) = flux_v(i, l)*densb(i)/slope
1184    END DO
1185  END DO
1186
1187  ! Calculate drag at intermediate levels using centered differences
1188
1189  DO l = lev1p, lev2m
1190    DO i = il1, il2
1191      IF (lorms(i)) THEN
1192        ! cc       DENDZ2 = DENSITY(I,L) * ( ALT(I,L+1) - ALT(I,L-1) )
1193        dendz2 = density(i, l)*(alt(i,l-1)-alt(i,l))
1194        ! cc       DRAG_U(I,L) = - ( FLUX_U(I,L+1) - FLUX_U(I,L-1) ) / DENDZ2
1195        drag_u(i, l) = -(flux_u(i,l-1)-flux_u(i,l))/dendz2
1196        ! cc       DRAG_V(I,L) = - ( FLUX_V(I,L+1) - FLUX_V(I,L-1) ) / DENDZ2
1197        drag_v(i, l) = -(flux_v(i,l-1)-flux_v(i,l))/dendz2
1198
1199      END IF
1200    END DO
1201  END DO
1202
1203  ! Drag at first and last levels using one-side differences.
1204
1205  DO i = il1, il2
1206    IF (lorms(i)) THEN
1207      dendz = density(i, lev1)*(alt(i,lev1)-alt(i,lev1p))
1208      drag_u(i, lev1) = flux_u(i, lev1)/dendz
1209      drag_v(i, lev1) = flux_v(i, lev1)/dendz
1210    END IF
1211  END DO
1212  DO i = il1, il2
1213    IF (lorms(i)) THEN
1214      dendz = density(i, lev2)*(alt(i,lev2m)-alt(i,lev2))
1215      drag_u(i, lev2) = -(flux_u(i,lev2m)-flux_u(i,lev2))/dendz
1216      drag_v(i, lev2) = -(flux_v(i,lev2m)-flux_v(i,lev2))/dendz
1217    END IF
1218  END DO
1219  IF (nlevs>lev2) THEN
1220    DO i = il1, il2
1221      IF (lorms(i)) THEN
1222        dendz = density(i, lev2p)*(alt(i,lev2)-alt(i,lev2p))
1223        drag_u(i, lev2p) = -flux_u(i, lev2)/dendz
1224        drag_v(i, lev2p) = -flux_v(i, lev2)/dendz
1225      END IF
1226    END DO
1227  END IF
1228
1229  RETURN
1230  ! -----------------------------------------------------------------------
1231END SUBROUTINE hines_flux
1232
1233SUBROUTINE hines_heat(heat, diffco, m_alpha, dmdz_alpha, ak_alpha, k_alpha, &
1234    bvfreq, density, densb, sigma_t, visc_mol, kstar, slope, f2, f3, f5, f6, &
1235    naz, il1, il2, lev1, lev2, nlons, nlevs, nazmth)
1236
1237  ! This routine calculates the gravity wave induced heating and
1238  ! diffusion coefficient on a longitude by altitude grid for
1239  ! the Hines' Doppler spread gravity wave drag parameterization scheme.
1240
1241  ! Aug. 6/95 - C. McLandress
1242
1243  ! Output arguements:
1244
1245  ! * HEAT   = gravity wave heating (K/sec).
1246  ! * DIFFCO = diffusion coefficient (m^2/sec)
1247
1248  ! Input arguements:
1249
1250  ! * M_ALPHA     = cutoff vertical wavenumber (1/m).
1251  ! * DMDZ_ALPHA  = vertical derivative of cutoff wavenumber.
1252  ! * AK_ALPHA    = spectral amplitude factor of each azimuth
1253  ! (i.e., {AjKj} in m^4/s^2).
1254  ! * K_ALPHA     = horizontal wavenumber of each azimuth (1/m).
1255  ! * BVFREQ      = background Brunt Vassala frequency (rad/sec).
1256  ! * DENSITY     = background density (kg/m^3).
1257  ! * DENSB       = background density at bottom level (kg/m^3).
1258  ! * SIGMA_T     = total rms horizontal wind (m/s).
1259  ! * VISC_MOL    = molecular viscosity (m^2/s).
1260  ! * KSTAR       = typical gravity wave horizontal wavenumber (1/m).
1261  ! * SLOPE       = slope of incident vertical wavenumber spectrum.
1262  ! * F2,F3,F5,F6 = Hines's fudge factors.
1263  ! * NAZ         = actual number of horizontal azimuths used.
1264  ! * IL1         = first longitudinal index to use (IL1 >= 1).
1265  ! * IL2         = last longitudinal index to use (IL1 <= IL2 <= NLONS).
1266  ! * LEV1        = first altitude level to use (LEV1 >=1).
1267  ! * LEV2        = last altitude level to use (LEV1 < LEV2 <= NLEVS).
1268  ! * NLONS       = number of longitudes.
1269  ! * NLEVS       = number of vertical levels.
1270  ! * NAZMTH      = azimuthal array dimension (NAZMTH >= NAZ).
1271
1272  INTEGER naz, il1, il2, lev1, lev2, nlons, nlevs, nazmth
1273  REAL kstar(nlons), slope, f2, f3, f5, f6
1274  REAL heat(nlons, nlevs), diffco(nlons, nlevs)
1275  REAL m_alpha(nlons, nlevs, nazmth), dmdz_alpha(nlons, nlevs, nazmth)
1276  REAL ak_alpha(nlons, nazmth), k_alpha(nlons, nazmth)
1277  REAL bvfreq(nlons, nlevs), density(nlons, nlevs), densb(nlons)
1278  REAL sigma_t(nlons, nlevs), visc_mol(nlons, nlevs)
1279
1280  ! Internal variables.
1281
1282  INTEGER i, l, n
1283  REAL m_sub_m_turb, m_sub_m_mol, m_sub_m, heatng
1284  REAL visc, visc_min, cpgas, sm1
1285
1286  ! specific heat at constant pressure
1287
1288  DATA cpgas/1004./
1289
1290  ! minimum permissible viscosity
1291
1292  DATA visc_min/1.E-10/
1293  ! -----------------------------------------------------------------------
1294
1295  ! Initialize heating array.
1296
1297  DO l = 1, nlevs
1298    DO i = 1, nlons
1299      heat(i, l) = 0.
1300    END DO
1301  END DO
1302
1303  ! Perform sum over azimuths for case where SLOPE = 1.
1304
1305  IF (slope==1.) THEN
1306    DO n = 1, naz
1307      DO l = lev1, lev2
1308        DO i = il1, il2
1309          heat(i, l) = heat(i, l) + ak_alpha(i, n)*k_alpha(i, n)*dmdz_alpha(i &
1310            , l, n)
1311        END DO
1312      END DO
1313    END DO
1314  END IF
1315
1316  ! Perform sum over azimuths for case where SLOPE not 1.
1317
1318  IF (slope/=1.) THEN
1319    sm1 = slope - 1.
1320    DO n = 1, naz
1321      DO l = lev1, lev2
1322        DO i = il1, il2
1323          heat(i, l) = heat(i, l) + ak_alpha(i, n)*k_alpha(i, n)*m_alpha(i, l &
1324            , n)**sm1*dmdz_alpha(i, l, n)
1325        END DO
1326      END DO
1327    END DO
1328  END IF
1329
1330  ! Heating and diffusion.
1331
1332  DO l = lev1, lev2
1333    DO i = il1, il2
1334
1335      ! Maximum permissible value of cutoff wavenumber is the smaller
1336      ! of the instability-induced wavenumber (M_SUB_M_TURB) and
1337      ! that imposed by molecular viscosity (M_SUB_M_MOL).
1338
1339      visc = amax1(visc_mol(i,l), visc_min)
1340      m_sub_m_turb = bvfreq(i, l)/(f2*sigma_t(i,l))
1341      m_sub_m_mol = (bvfreq(i,l)*kstar(i)/visc)**0.33333333/f3
1342      m_sub_m = amin1(m_sub_m_turb, m_sub_m_mol)
1343
1344      heatng = -heat(i, l)*f5*bvfreq(i, l)/m_sub_m*densb(i)/density(i, l)
1345      diffco(i, l) = f6*heatng**0.33333333/m_sub_m**1.33333333
1346      heat(i, l) = heatng/cpgas
1347
1348    END DO
1349  END DO
1350
1351  RETURN
1352  ! -----------------------------------------------------------------------
1353END SUBROUTINE hines_heat
1354
1355SUBROUTINE hines_sigma(sigma_t, sigma_alpha, sigsqh_alpha, naz, lev, il1, &
1356    il2, nlons, nlevs, nazmth)
1357
1358  ! This routine calculates the total rms and azimuthal rms horizontal
1359  ! velocities at a given level on a longitude by altitude grid for
1360  ! the Hines' Doppler spread GWD parameterization scheme.
1361  ! NOTE: only four or eight azimuths can be used.
1362
1363  ! Aug. 7/95 - C. McLandress
1364
1365  ! Output arguements:
1366
1367  ! * SIGMA_T      = total rms horizontal wind (m/s).
1368  ! * SIGMA_ALPHA  = total rms wind in each azimuth (m/s).
1369
1370  ! Input arguements:
1371
1372  ! * SIGSQH_ALPHA = portion of wind variance from waves having wave
1373  ! *                normals in the alpha azimuth (m/s).
1374  ! * NAZ       = actual number of horizontal azimuths used (must be 4 or 8).
1375  ! * LEV       = altitude level to process.
1376  ! * IL1       = first longitudinal index to use (IL1 >= 1).
1377  ! * IL2       = last longitudinal index to use (IL1 <= IL2 <= NLONS).
1378  ! * NLONS     = number of longitudes.
1379  ! * NLEVS     = number of vertical levels.
1380  ! * NAZMTH    = azimuthal array dimension (NAZMTH >= NAZ).
1381
1382  ! Subroutine arguements.
1383
1384  INTEGER lev, naz, il1, il2
1385  INTEGER nlons, nlevs, nazmth
1386  REAL sigma_t(nlons, nlevs)
1387  REAL sigma_alpha(nlons, nlevs, nazmth)
1388  REAL sigsqh_alpha(nlons, nlevs, nazmth)
1389
1390  ! Internal variables.
1391
1392  INTEGER i, n
1393  REAL sum_even, sum_odd
1394  ! -----------------------------------------------------------------------
1395
1396  ! Calculate azimuthal rms velocity for the 4 azimuth case.
1397
1398  IF (naz==4) THEN
1399    DO i = il1, il2
1400      sigma_alpha(i, lev, 1) = sqrt(sigsqh_alpha(i,lev,1)+sigsqh_alpha(i,lev, &
1401        3))
1402      sigma_alpha(i, lev, 2) = sqrt(sigsqh_alpha(i,lev,2)+sigsqh_alpha(i,lev, &
1403        4))
1404      sigma_alpha(i, lev, 3) = sigma_alpha(i, lev, 1)
1405      sigma_alpha(i, lev, 4) = sigma_alpha(i, lev, 2)
1406    END DO
1407  END IF
1408
1409  ! Calculate azimuthal rms velocity for the 8 azimuth case.
1410
1411  IF (naz==8) THEN
1412    DO i = il1, il2
1413      sum_odd = (sigsqh_alpha(i,lev,1)+sigsqh_alpha(i,lev,3)+ &
1414        sigsqh_alpha(i,lev,5)+sigsqh_alpha(i,lev,7))/2.
1415      sum_even = (sigsqh_alpha(i,lev,2)+sigsqh_alpha(i,lev,4)+ &
1416        sigsqh_alpha(i,lev,6)+sigsqh_alpha(i,lev,8))/2.
1417      sigma_alpha(i, lev, 1) = sqrt(sigsqh_alpha(i,lev,1)+sigsqh_alpha(i,lev, &
1418        5)+sum_even)
1419      sigma_alpha(i, lev, 2) = sqrt(sigsqh_alpha(i,lev,2)+sigsqh_alpha(i,lev, &
1420        6)+sum_odd)
1421      sigma_alpha(i, lev, 3) = sqrt(sigsqh_alpha(i,lev,3)+sigsqh_alpha(i,lev, &
1422        7)+sum_even)
1423      sigma_alpha(i, lev, 4) = sqrt(sigsqh_alpha(i,lev,4)+sigsqh_alpha(i,lev, &
1424        8)+sum_odd)
1425      sigma_alpha(i, lev, 5) = sigma_alpha(i, lev, 1)
1426      sigma_alpha(i, lev, 6) = sigma_alpha(i, lev, 2)
1427      sigma_alpha(i, lev, 7) = sigma_alpha(i, lev, 3)
1428      sigma_alpha(i, lev, 8) = sigma_alpha(i, lev, 4)
1429    END DO
1430  END IF
1431
1432  ! Calculate total rms velocity.
1433
1434  DO i = il1, il2
1435    sigma_t(i, lev) = 0.
1436  END DO
1437  DO n = 1, naz
1438    DO i = il1, il2
1439      sigma_t(i, lev) = sigma_t(i, lev) + sigsqh_alpha(i, lev, n)
1440    END DO
1441  END DO
1442  DO i = il1, il2
1443    sigma_t(i, lev) = sqrt(sigma_t(i,lev))
1444  END DO
1445
1446  RETURN
1447  ! -----------------------------------------------------------------------
1448END SUBROUTINE hines_sigma
1449
1450SUBROUTINE hines_intgrl(i_alpha, v_alpha, m_alpha, bvfb, slope, naz, lev, &
1451    il1, il2, nlons, nlevs, nazmth, lorms)
1452
1453  ! This routine calculates the vertical wavenumber integral
1454  ! for a single vertical level at each azimuth on a longitude grid
1455  ! for the Hines' Doppler spread GWD parameterization scheme.
1456  ! NOTE: (1) only spectral slopes of 1, 1.5 or 2 are permitted.
1457  ! (2) the integral is written in terms of the product QM
1458  ! which by construction is always less than 1. Series
1459  ! solutions are used for small |QM| and analytical solutions
1460  ! for remaining values.
1461
1462  ! Aug. 8/95 - C. McLandress
1463
1464  ! Output arguement:
1465
1466  ! * I_ALPHA = Hines' integral.
1467
1468  ! Input arguements:
1469
1470  ! * V_ALPHA = azimuthal wind component (m/s).
1471  ! * M_ALPHA = azimuthal cutoff vertical wavenumber (1/m).
1472  ! * BVFB    = background Brunt Vassala frequency at model bottom.
1473  ! * SLOPE   = slope of initial vertical wavenumber spectrum
1474  ! *           (must use SLOPE = 1., 1.5 or 2.)
1475  ! * NAZ     = actual number of horizontal azimuths used.
1476  ! * LEV     = altitude level to process.
1477  ! * IL1     = first longitudinal index to use (IL1 >= 1).
1478  ! * IL2     = last longitudinal index to use (IL1 <= IL2 <= NLONS).
1479  ! * NLONS   = number of longitudes.
1480  ! * NLEVS   = number of vertical levels.
1481  ! * NAZMTH  = azimuthal array dimension (NAZMTH >= NAZ).
1482
1483  ! * LORMS       = .TRUE. for drag computation
1484
1485  ! Constants in DATA statements:
1486
1487  ! * QMIN = minimum value of Q_ALPHA (avoids indeterminant form of integral)
1488  ! * QM_MIN = minimum value of Q_ALPHA * M_ALPHA (used to avoid numerical
1489  ! *          problems).
1490
1491  INTEGER lev, naz, il1, il2, nlons, nlevs, nazmth
1492  REAL i_alpha(nlons, nazmth)
1493  REAL v_alpha(nlons, nlevs, nazmth)
1494  REAL m_alpha(nlons, nlevs, nazmth)
1495  REAL bvfb(nlons), slope
1496
1497  LOGICAL lorms(nlons)
1498
1499  ! Internal variables.
1500
1501  INTEGER i, n
1502  REAL q_alpha, qm, sqrtqm, q_min, qm_min
1503
1504  DATA q_min/1.0/, qm_min/0.01/
1505  ! -----------------------------------------------------------------------
1506
1507  ! For integer value SLOPE = 1.
1508
1509  IF (slope==1.) THEN
1510
1511    DO n = 1, naz
1512      DO i = il1, il2
1513        IF (lorms(i)) THEN
1514
1515          q_alpha = v_alpha(i, lev, n)/bvfb(i)
1516          qm = q_alpha*m_alpha(i, lev, n)
1517
1518          ! If |QM| is small then use first 4 terms series of Taylor series
1519          ! expansion of integral in order to avoid indeterminate form of
1520          ! integral,
1521          ! otherwise use analytical form of integral.
1522
1523          IF (abs(q_alpha)<q_min .OR. abs(qm)<qm_min) THEN
1524            IF (q_alpha==0.) THEN
1525              i_alpha(i, n) = m_alpha(i, lev, n)**2/2.
1526            ELSE
1527              i_alpha(i, n) = (qm**2/2.+qm**3/3.+qm**4/4.+qm**5/5.)/ &
1528                q_alpha**2
1529            END IF
1530          ELSE
1531            i_alpha(i, n) = -(alog(1.-qm)+qm)/q_alpha**2
1532          END IF
1533
1534        END IF
1535      END DO
1536    END DO
1537
1538  END IF
1539
1540  ! For integer value SLOPE = 2.
1541
1542  IF (slope==2.) THEN
1543
1544    DO n = 1, naz
1545      DO i = il1, il2
1546        IF (lorms(i)) THEN
1547
1548          q_alpha = v_alpha(i, lev, n)/bvfb(i)
1549          qm = q_alpha*m_alpha(i, lev, n)
1550
1551          ! If |QM| is small then use first 4 terms series of Taylor series
1552          ! expansion of integral in order to avoid indeterminate form of
1553          ! integral,
1554          ! otherwise use analytical form of integral.
1555
1556          IF (abs(q_alpha)<q_min .OR. abs(qm)<qm_min) THEN
1557            IF (q_alpha==0.) THEN
1558              i_alpha(i, n) = m_alpha(i, lev, n)**3/3.
1559            ELSE
1560              i_alpha(i, n) = (qm**3/3.+qm**4/4.+qm**5/5.+qm**6/6.)/ &
1561                q_alpha**3
1562            END IF
1563          ELSE
1564            i_alpha(i, n) = -(alog(1.-qm)+qm+qm**2/2.)/q_alpha**3
1565          END IF
1566
1567        END IF
1568      END DO
1569    END DO
1570
1571  END IF
1572
1573  ! For real value SLOPE = 1.5
1574
1575  IF (slope==1.5) THEN
1576
1577    DO n = 1, naz
1578      DO i = il1, il2
1579        IF (lorms(i)) THEN
1580
1581          q_alpha = v_alpha(i, lev, n)/bvfb(i)
1582          qm = q_alpha*m_alpha(i, lev, n)
1583
1584          ! If |QM| is small then use first 4 terms series of Taylor series
1585          ! expansion of integral in order to avoid indeterminate form of
1586          ! integral,
1587          ! otherwise use analytical form of integral.
1588
1589          IF (abs(q_alpha)<q_min .OR. abs(qm)<qm_min) THEN
1590            IF (q_alpha==0.) THEN
1591              i_alpha(i, n) = m_alpha(i, lev, n)**2.5/2.5
1592            ELSE
1593              i_alpha(i, n) = (qm/2.5+qm**2/3.5+qm**3/4.5+qm**4/5.5)* &
1594                m_alpha(i, lev, n)**1.5/q_alpha
1595            END IF
1596          ELSE
1597            qm = abs(qm)
1598            sqrtqm = sqrt(qm)
1599            IF (q_alpha>=0.) THEN
1600              i_alpha(i, n) = (alog((1.+sqrtqm)/(1.-sqrtqm))-2.*sqrtqm*(1.+qm &
1601                /3.))/q_alpha**2.5
1602            ELSE
1603              i_alpha(i, n) = 2.*(atan(sqrtqm)+sqrtqm*(qm/3.-1.))/ &
1604                abs(q_alpha)**2.5
1605            END IF
1606          END IF
1607
1608        END IF
1609      END DO
1610    END DO
1611
1612  END IF
1613
1614  ! If integral is negative (which in principal should not happen) then
1615  ! print a message and some info since execution will abort when calculating
1616  ! the variances.
1617
1618  ! DO 80 N = 1,NAZ
1619  ! DO 70 I = IL1,IL2
1620  ! IF (I_ALPHA(I,N).LT.0.)  THEN
1621  ! WRITE (6,*)
1622  ! WRITE (6,*) '******************************'
1623  ! WRITE (6,*) 'Hines integral I_ALPHA < 0 '
1624  ! WRITE (6,*) '  longitude I=',I
1625  ! WRITE (6,*) '  azimuth   N=',N
1626  ! WRITE (6,*) '  level   LEV=',LEV
1627  ! WRITE (6,*) '  I_ALPHA =',I_ALPHA(I,N)
1628  ! WRITE (6,*) '  V_ALPHA =',V_ALPHA(I,LEV,N)
1629  ! WRITE (6,*) '  M_ALPHA =',M_ALPHA(I,LEV,N)
1630  ! WRITE (6,*) '  Q_ALPHA =',V_ALPHA(I,LEV,N) / BVFB(I)
1631  ! WRITE (6,*) '  QM      =',V_ALPHA(I,LEV,N) / BVFB(I)
1632  ! ^                                * M_ALPHA(I,LEV,N)
1633  ! WRITE (6,*) '******************************'
1634  ! END IF
1635  ! 70     CONTINUE
1636  ! 80   CONTINUE
1637
1638  RETURN
1639  ! -----------------------------------------------------------------------
1640END SUBROUTINE hines_intgrl
1641
1642SUBROUTINE hines_setup(naz, slope, f1, f2, f3, f5, f6, kstar, icutoff, &
1643    alt_cutoff, smco, nsmax, iheatcal, k_alpha, ierror, nmessg, nlons, &
1644    nazmth, coslat)
1645
1646  ! This routine specifies various parameters needed for the
1647  ! the Hines' Doppler spread gravity wave drag parameterization scheme.
1648
1649  ! Aug. 8/95 - C. McLandress
1650
1651  ! Output arguements:
1652
1653  ! * NAZ        = actual number of horizontal azimuths used
1654  ! *              (code set up presently for only NAZ = 4 or 8).
1655  ! * SLOPE      = slope of incident vertical wavenumber spectrum
1656  ! *              (code set up presently for SLOPE 1., 1.5 or 2.).
1657  ! * F1         = "fudge factor" used in calculation of trial value of
1658  ! *              azimuthal cutoff wavenumber M_ALPHA (1.2 <= F1 <= 1.9).
1659  ! * F2         = "fudge factor" used in calculation of maximum
1660  ! *              permissible instabiliy-induced cutoff wavenumber
1661  ! *              M_SUB_M_TURB (0.1 <= F2 <= 1.4).
1662  ! * F3         = "fudge factor" used in calculation of maximum
1663  ! *              permissible molecular viscosity-induced cutoff wavenumber
1664  ! *              M_SUB_M_MOL (0.1 <= F2 <= 1.4).
1665  ! * F5         = "fudge factor" used in calculation of heating rate
1666  ! *              (1 <= F5 <= 3).
1667  ! * F6         = "fudge factor" used in calculation of turbulent
1668  ! *              diffusivity coefficient.
1669  ! * KSTAR      = typical gravity wave horizontal wavenumber (1/m)
1670  ! *              used in calculation of M_SUB_M_TURB.
1671  ! * ICUTOFF    = 1 to exponentially damp off GWD, heating and diffusion
1672  ! *              arrays above ALT_CUTOFF; otherwise arrays not modified.
1673  ! * ALT_CUTOFF = altitude in meters above which exponential decay applied.
1674  ! * SMCO       = smoother used to smooth cutoff vertical wavenumbers
1675  ! *              and total rms winds before calculating drag or heating.
1676  ! *              (==> a 1:SMCO:1 stencil used; SMCO >= 1.).
1677  ! * NSMAX      = number of times smoother applied ( >= 1),
1678  ! *            = 0 means no smoothing performed.
1679  ! * IHEATCAL   = 1 to calculate heating rates and diffusion coefficient.
1680  ! *            = 0 means only drag and flux calculated.
1681  ! * K_ALPHA    = horizontal wavenumber of each azimuth (1/m) which
1682  ! *              is set here to KSTAR.
1683  ! * IERROR     = error flag.
1684  ! *            = 0 no errors.
1685  ! *            = 10 ==> NAZ > NAZMTH
1686  ! *            = 20 ==> invalid number of azimuths (NAZ must be 4 or 8).
1687  ! *            = 30 ==> invalid slope (SLOPE must be 1., 1.5 or 2.).
1688  ! *            = 40 ==> invalid smoother (SMCO must be >= 1.)
1689
1690  ! Input arguements:
1691
1692  ! * NMESSG  = output unit number where messages to be printed.
1693  ! * NLONS   = number of longitudes.
1694  ! * NAZMTH  = azimuthal array dimension (NAZMTH >= NAZ).
1695
1696  INTEGER naz, nlons, nazmth, iheatcal, icutoff
1697  INTEGER nmessg, nsmax, ierror
1698  REAL kstar(nlons), slope, f1, f2, f3, f5, f6, alt_cutoff, smco
1699  REAL k_alpha(nlons, nazmth), coslat(nlons)
1700  REAL ksmin, ksmax
1701
1702  ! Internal variables.
1703
1704  INTEGER i, n
1705  ! -----------------------------------------------------------------------
1706
1707  ! Specify constants.
1708
1709  naz = 8
1710  slope = 1.
1711  f1 = 1.5
1712  f2 = 0.3
1713  f3 = 1.0
1714  f5 = 3.0
1715  f6 = 1.0
1716  ksmin = 1.E-5
1717  ksmax = 1.E-4
1718  DO i = 1, nlons
1719    kstar(i) = ksmin/(coslat(i)+(ksmin/ksmax))
1720  END DO
1721  icutoff = 1
1722  alt_cutoff = 105.E3
1723  smco = 2.0
1724  ! SMCO       = 1.0
1725  nsmax = 5
1726  ! NSMAX      = 2
1727  iheatcal = 0
1728
1729  ! Print information to output file.
1730
1731  ! WRITE (NMESSG,6000)
1732  ! 6000 FORMAT (/' Subroutine HINES_SETUP:')
1733  ! WRITE (NMESSG,*)  '  SLOPE = ', SLOPE
1734  ! WRITE (NMESSG,*)  '  NAZ = ', NAZ
1735  ! WRITE (NMESSG,*)  '  F1,F2,F3  = ', F1, F2, F3
1736  ! WRITE (NMESSG,*)  '  F5,F6     = ', F5, F6
1737  ! WRITE (NMESSG,*)  '  KSTAR     = ', KSTAR
1738  ! >           ,'  COSLAT     = ', COSLAT
1739  ! IF (ICUTOFF .EQ. 1)  THEN
1740  ! WRITE (NMESSG,*) '  Drag exponentially damped above ',
1741  ! &                       ALT_CUTOFF/1.E3
1742  ! END IF
1743  ! IF (NSMAX.LT.1 )  THEN
1744  ! WRITE (NMESSG,*) '  No smoothing of cutoff wavenumbers, etc'
1745  ! ELSE
1746  ! WRITE (NMESSG,*) '  Cutoff wavenumbers and sig_t smoothed:'
1747  ! WRITE (NMESSG,*) '    SMCO  =', SMCO
1748  ! WRITE (NMESSG,*) '    NSMAX =', NSMAX
1749  ! END IF
1750
1751  ! Check that things are setup correctly and log error if not
1752
1753  ierror = 0
1754  IF (naz>nazmth) ierror = 10
1755  IF (naz/=4 .AND. naz/=8) ierror = 20
1756  IF (slope/=1. .AND. slope/=1.5 .AND. slope/=2.) ierror = 30
1757  IF (smco<1.) ierror = 40
1758
1759  ! Use single value for azimuthal-dependent horizontal wavenumber.
1760
1761  DO n = 1, naz
1762    DO i = 1, nlons
1763      k_alpha(i, n) = kstar(i)
1764    END DO
1765  END DO
1766
1767  RETURN
1768  ! -----------------------------------------------------------------------
1769END SUBROUTINE hines_setup
1770
1771SUBROUTINE hines_print(flux_u, flux_v, drag_u, drag_v, alt, sigma_t, &
1772    sigma_alpha, v_alpha, m_alpha, iu_print, iv_print, nmessg, ilprt1, &
1773    ilprt2, levprt1, levprt2, naz, nlons, nlevs, nazmth)
1774
1775  ! Print out altitude profiles of various quantities from
1776  ! Hines' Doppler spread gravity wave drag parameterization scheme.
1777  ! (NOTE: only for NAZ = 4 or 8).
1778
1779  ! Aug. 8/95 - C. McLandress
1780
1781  ! Input arguements:
1782
1783  ! * IU_PRINT = 1 to print out values in east-west direction.
1784  ! * IV_PRINT = 1 to print out values in north-south direction.
1785  ! * NMESSG   = unit number for printed output.
1786  ! * ILPRT1   = first longitudinal index to print.
1787  ! * ILPRT2   = last longitudinal index to print.
1788  ! * LEVPRT1  = first altitude level to print.
1789  ! * LEVPRT2  = last altitude level to print.
1790
1791  INTEGER naz, ilprt1, ilprt2, levprt1, levprt2
1792  INTEGER nlons, nlevs, nazmth
1793  INTEGER iu_print, iv_print, nmessg
1794  REAL flux_u(nlons, nlevs), flux_v(nlons, nlevs)
1795  REAL drag_u(nlons, nlevs), drag_v(nlons, nlevs)
1796  REAL alt(nlons, nlevs), sigma_t(nlons, nlevs)
1797  REAL sigma_alpha(nlons, nlevs, nazmth)
1798  REAL v_alpha(nlons, nlevs, nazmth), m_alpha(nlons, nlevs, nazmth)
1799
1800  ! Internal variables.
1801
1802  INTEGER n_east, n_west, n_north, n_south
1803  INTEGER i, l
1804  ! -----------------------------------------------------------------------
1805
1806  ! Azimuthal indices of cardinal directions.
1807
1808  n_east = 1
1809  IF (naz==4) THEN
1810    n_west = 3
1811    n_north = 2
1812    n_south = 4
1813  ELSE IF (naz==8) THEN
1814    n_west = 5
1815    n_north = 3
1816    n_south = 7
1817  END IF
1818
1819  ! Print out values for range of longitudes.
1820
1821  DO i = ilprt1, ilprt2
1822
1823    ! Print east-west wind, sigmas, cutoff wavenumbers, flux and drag.
1824
1825    IF (iu_print==1) THEN
1826      WRITE (nmessg, *)
1827      WRITE (nmessg, 6001) i
1828      WRITE (nmessg, 6005)
18296001  FORMAT ('Hines GW (east-west) at longitude I =', I3)
18306005  FORMAT (15X, ' U ', 2X, 'sig_E', 2X, 'sig_T', 3X, 'm_E', 4X, 'm_W', 4X, &
1831        'fluxU', 5X, 'gwdU')
1832      DO l = levprt1, levprt2
1833        WRITE (nmessg, 6701) alt(i, l)/1.E3, v_alpha(i, l, n_east), &
1834          sigma_alpha(i, l, n_east), sigma_t(i, l), &
1835          m_alpha(i, l, n_east)*1.E3, m_alpha(i, l, n_west)*1.E3, &
1836          flux_u(i, l)*1.E5, drag_u(i, l)*24.*3600.
1837      END DO
18386701  FORMAT (' z=', F7.2, 1X, 3F7.1, 2F7.3, F9.4, F9.3)
1839    END IF
1840
1841    ! Print north-south winds, sigmas, cutoff wavenumbers, flux and drag.
1842
1843    IF (iv_print==1) THEN
1844      WRITE (nmessg, *)
1845      WRITE (nmessg, 6002) i
18466002  FORMAT ('Hines GW (north-south) at longitude I =', I3)
1847      WRITE (nmessg, 6006)
18486006  FORMAT (15X, ' V ', 2X, 'sig_N', 2X, 'sig_T', 3X, 'm_N', 4X, 'm_S', 4X, &
1849        'fluxV', 5X, 'gwdV')
1850      DO l = levprt1, levprt2
1851        WRITE (nmessg, 6701) alt(i, l)/1.E3, v_alpha(i, l, n_north), &
1852          sigma_alpha(i, l, n_north), sigma_t(i, l), &
1853          m_alpha(i, l, n_north)*1.E3, m_alpha(i, l, n_south)*1.E3, &
1854          flux_v(i, l)*1.E5, drag_v(i, l)*24.*3600.
1855      END DO
1856    END IF
1857
1858  END DO
1859
1860  RETURN
1861  ! -----------------------------------------------------------------------
1862END SUBROUTINE hines_print
1863
1864SUBROUTINE hines_exp(data, data_zmax, alt, alt_exp, iorder, il1, il2, lev1, &
1865    lev2, nlons, nlevs)
1866
1867  ! This routine exponentially damps a longitude by altitude array
1868  ! of data above a specified altitude.
1869
1870  ! Aug. 13/95 - C. McLandress
1871
1872  ! Output arguements:
1873
1874  ! * DATA = modified data array.
1875
1876  ! Input arguements:
1877
1878  ! * DATA    = original data array.
1879  ! * ALT     = altitudes.
1880  ! * ALT_EXP = altitude above which exponential decay applied.
1881  ! * IORDER    = 1 means vertical levels are indexed from top down
1882  ! *           (i.e., highest level indexed 1 and lowest level NLEVS);
1883  ! *           .NE. 1 highest level is index NLEVS.
1884  ! * IL1     = first longitudinal index to use (IL1 >= 1).
1885  ! * IL2     = last longitudinal index to use (IL1 <= IL2 <= NLONS).
1886  ! * LEV1    = first altitude level to use (LEV1 >=1).
1887  ! * LEV2    = last altitude level to use (LEV1 < LEV2 <= NLEVS).
1888  ! * NLONS   = number of longitudes.
1889  ! * NLEVS   = number of vertical
1890
1891  ! Input work arrays:
1892
1893  ! * DATA_ZMAX = data values just above altitude ALT_EXP.
1894
1895  INTEGER iorder, il1, il2, lev1, lev2, nlons, nlevs
1896  REAL alt_exp
1897  REAL data(nlons, nlevs), data_zmax(nlons), alt(nlons, nlevs)
1898
1899  ! Internal variables.
1900
1901  INTEGER levbot, levtop, lincr, i, l
1902  REAL hscale
1903  DATA hscale/5.E3/
1904  ! -----------------------------------------------------------------------
1905
1906  ! Index of lowest altitude level (bottom of drag calculation).
1907
1908  levbot = lev2
1909  levtop = lev1
1910  lincr = 1
1911  IF (iorder/=1) THEN
1912    levbot = lev1
1913    levtop = lev2
1914    lincr = -1
1915  END IF
1916
1917  ! Data values at first level above ALT_EXP.
1918
1919  DO i = il1, il2
1920    DO l = levtop, levbot, lincr
1921      IF (alt(i,l)>=alt_exp) THEN
1922        data_zmax(i) = data(i, l)
1923      END IF
1924    END DO
1925  END DO
1926
1927  ! Exponentially damp field above ALT_EXP to model top at L=1.
1928
1929  DO l = 1, lev2
1930    DO i = il1, il2
1931      IF (alt(i,l)>=alt_exp) THEN
1932        data(i, l) = data_zmax(i)*exp((alt_exp-alt(i,l))/hscale)
1933      END IF
1934    END DO
1935  END DO
1936
1937  RETURN
1938  ! -----------------------------------------------------------------------
1939END SUBROUTINE hines_exp
1940
1941SUBROUTINE vert_smooth(data, work, coeff, nsmooth, il1, il2, lev1, lev2, &
1942    nlons, nlevs)
1943
1944  ! Smooth a longitude by altitude array in the vertical over a
1945  ! specified number of levels using a three point smoother.
1946
1947  ! NOTE: input array DATA is modified on output!
1948
1949  ! Aug. 3/95 - C. McLandress
1950
1951  ! Output arguement:
1952
1953  ! * DATA    = smoothed array (on output).
1954
1955  ! Input arguements:
1956
1957  ! * DATA    = unsmoothed array of data (on input).
1958  ! * WORK    = work array of same dimension as DATA.
1959  ! * COEFF   = smoothing coefficient for a 1:COEFF:1 stencil.
1960  ! *           (e.g., COEFF = 2 will result in a smoother which
1961  ! *           weights the level L gridpoint by two and the two
1962  ! *           adjecent levels (L+1 and L-1) by one).
1963  ! * NSMOOTH = number of times to smooth in vertical.
1964  ! *           (e.g., NSMOOTH=1 means smoothed only once,
1965  ! *           NSMOOTH=2 means smoothing repeated twice, etc.)
1966  ! * IL1     = first longitudinal index to use (IL1 >= 1).
1967  ! * IL2     = last longitudinal index to use (IL1 <= IL2 <= NLONS).
1968  ! * LEV1    = first altitude level to use (LEV1 >=1).
1969  ! * LEV2    = last altitude level to use (LEV1 < LEV2 <= NLEVS).
1970  ! * NLONS   = number of longitudes.
1971  ! * NLEVS   = number of vertical levels.
1972
1973  ! Subroutine arguements.
1974
1975  INTEGER nsmooth, il1, il2, lev1, lev2, nlons, nlevs
1976  REAL coeff
1977  REAL data(nlons, nlevs), work(nlons, nlevs)
1978
1979  ! Internal variables.
1980
1981  INTEGER i, l, ns, lev1p, lev2m
1982  REAL sum_wts
1983  ! -----------------------------------------------------------------------
1984
1985  ! Calculate sum of weights.
1986
1987  sum_wts = coeff + 2.
1988
1989  lev1p = lev1 + 1
1990  lev2m = lev2 - 1
1991
1992  ! Smooth NSMOOTH times
1993
1994  DO ns = 1, nsmooth
1995
1996    ! Copy data into work array.
1997
1998    DO l = lev1, lev2
1999      DO i = il1, il2
2000        work(i, l) = data(i, l)
2001      END DO
2002    END DO
2003
2004    ! Smooth array WORK in vertical direction and put into DATA.
2005
2006    DO l = lev1p, lev2m
2007      DO i = il1, il2
2008        data(i, l) = (work(i,l+1)+coeff*work(i,l)+work(i,l-1))/sum_wts
2009      END DO
2010    END DO
2011
2012  END DO
2013
2014  RETURN
2015  ! -----------------------------------------------------------------------
2016END SUBROUTINE vert_smooth
2017
2018
2019
2020
2021
2022
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