1 |
C $Header: /u/gcmpack/MITgcm/pkg/fizhi/fizhi_turb.F,v 1.26 2004/09/09 20:51:09 molod Exp $ |
2 |
C $Name: $ |
3 |
|
4 |
#include "FIZHI_OPTIONS.h" |
5 |
subroutine turbio (im,jm,nlay,istrip,nymd,nhms,bi,bj |
6 |
1 ,ndturb,ptop, pz, uz, vz, tz, qz, ntracers,ptracers |
7 |
2 ,plz,plze,dpres,pkht,pkz,ctmt,xxmt,yymt,zetamt,xlmt,khmt,tke |
8 |
3 ,tgz,fracland,landtype |
9 |
4 ,tcanopy,ecanopy,tdeep,swetshal,swetroot,swetdeep,snodep,capac |
10 |
5 ,nchp,nchptot,nchplnd,chfr,chlt,chlon,igrd,ityp,alai,agrn,thkz |
11 |
6 ,tprof |
12 |
8 ,duturb, dvturb, dtturb,dqturb,radlwg,st4,dst4,radswg,radswt |
13 |
9 ,fdifpar,fdirpar,rainlsp,rainconv,snowfall,tempref |
14 |
1 ,imstturblw,imstturbsw,qliqavelw,qliqavesw,fccavelw,fccavesw |
15 |
2 ,qqgrid,myid) |
16 |
c----------------------------------------------------------------------- |
17 |
c subroutine turbio - model interface routine to trbflx, the turbulence |
18 |
c parameterization, and tile, the land surface parameterization |
19 |
c |
20 |
c input: |
21 |
c im - number of points in the longitude direction |
22 |
c jm - number of points in the latitude direction |
23 |
c nlay - number of vertical levels |
24 |
c istrip - number of horizontal points to be handled at a time on |
25 |
c nymd - year and date integer in YYMMDD format (ie, 790212) |
26 |
c nhms - date and time integer in HHMMSS format (ie, 123000) |
27 |
c ndturb - turbulence time step integer in HHMMSS format |
28 |
c ptop - model top pressure - rigid lid assumed - real |
29 |
c pz - surface pressure minus ptop in mb - real[lon,lat] |
30 |
c uz - zonal wind in m/sec - real[lon,lat,level] |
31 |
c vz - meridional wind in m/sec - real[lon,lat,level] |
32 |
c tz - model theta (theta [deg K]/p0**k) - real[lon,lat,level] |
33 |
c qz - specific humidity in kg/kg - real[lon,lat,level] |
34 |
c ntracers- total number of tracers - integer |
35 |
c ptracers- number of permanent tracers - integer |
36 |
c pkht - pressure[mb]**k at bottom edges of levels - real[lon,lat,level] |
37 |
c fracland- not being used - real[lon,lat] |
38 |
c landtype- not being used - integer[lon,lat] |
39 |
c nchp - nchplnd<nchp - total no chips (ocean too) - integer |
40 |
c nchplnd - <=nchp - number of land chips - integer |
41 |
c chfr - chip fraction - real[nchp] |
42 |
c chlt - tile space latitude array - real[nchp] |
43 |
c chlon - tile space longitude array - real[nchp] |
44 |
c igrd - tile space grid number - integer[nchp] |
45 |
c ityp - tile space vegetation type - integer[nchp] |
46 |
c alai - leaf area index - real[nchp] |
47 |
c agrn - greenness fraction - real[nchp] |
48 |
c thkz - sea ice thickness in m (0. for no ice) - real[lon,lat] |
49 |
c tprof - logical flag for point by point diagnostic output |
50 |
c ndiagsiz- number of diagnostic 2-D arrays allocated |
51 |
c ndlsm - number of tile diagnostic |
52 |
c radlwg - net longwave flux at ground (up-down) in w/m**2 - real[lon,lat] |
53 |
c st4 - upward longwave flux at ground in w/m**2 - real[lon,lat] |
54 |
c dst4 - delta-sigma-T**4, ie, derivative of upward lw flux at |
55 |
c ground with respect to ground Temperature - real[lon,lat] |
56 |
c radswg - net shortwave flux at ground (down-up) NON-DIM - real[lon,lat] |
57 |
c {NOTE: this field is divided by the incident shortwave |
58 |
c at the top of the atmosphere to non-dimensionalize] |
59 |
c radswt - incident shortwave at top of atmos in W/m**2 - real[lon,lat] |
60 |
c fdifpar - incident diffuse-beam PAR at surface in W/m**2 - real[lon,lat] |
61 |
c fdirpar - incident direct-beam PAR at surface in W/m**2 - real[lon,lat] |
62 |
c rainlsp - large-scale (frontal,supersat) rainfall in mm/sec - real[lon,lat] |
63 |
c rainconv- convective rainfall rate in mm/sec - real[lon,lat] |
64 |
c snowfall- total snowfall rate in mm/sec - real[lon,lat] |
65 |
c updated: |
66 |
c tke - turbulent k.e. in m**2/s**2 - real[tiles,levels] |
67 |
c tgz - surface skin temperature in deg K - real[lon,lat] |
68 |
c tcanopy - canopy temperature in deg K real[tiles] |
69 |
c (sea surface temp over the ocean tiles) |
70 |
c ecanopy - canopy vapor pressure in mb real[tiles] |
71 |
c (qstar at tground over the sea ice and ocean tiles) |
72 |
c tdeep - deep soil temp in deg K real[tiles] |
73 |
c swetshal- shallow level moisture field capacity fraction real[tiles] |
74 |
c swetroot- root level moisture field capacity fraction real[tiles] |
75 |
c swetdeep- deep soil level moisture field capacity fraction real[tiles] |
76 |
c snodep - depth of snow pack in cm liquid water equiv real[tiles] |
77 |
c capac - leaf canopy water reservoir in cm real[tiles] |
78 |
c output: |
79 |
c duturb - change in zonal wind component due to turbulent processes |
80 |
c per unit time in m/sec**2 - real[lon,lat,levels] |
81 |
c dvturb - change in meridional wind component due to turbulent processes |
82 |
c per unit time in m/sec**2 - real[lon,lat,levels] |
83 |
c dtturb - change in (model theta*pi) due to turbulent processes |
84 |
c per unit time - real[lon,lat,levels] !! pi is pressure-ptop |
85 |
c dqturb - change in (specific humidity*pi) due to turbulent processes |
86 |
c per unit time - real[lon,lat,levels] !! pi is pressure-ptop |
87 |
c qliqavelw - Moist Turbulence Liquid Water for Longwave - real[lon,lat,levels] |
88 |
c qliqavesw - Moist Turbulence Liquid Water for Shortwave - real[lon,lat,levels] |
89 |
c fccavelw - Moist Turbulence Cloud Fraction for Longwave - real[lon,lat,levels] |
90 |
c fccavesw - Moist Turbulence Cloud Fraction for Shortwave - real[lon,lat,levels] |
91 |
c qqgrid - Gridded Turbulent Kinetic Energy - real[lon,lat,levels] |
92 |
c----------------------------------------------------------------------- |
93 |
implicit none |
94 |
|
95 |
#ifdef ALLOW_USE_MPI |
96 |
#include "mpif.h" |
97 |
#endif |
98 |
|
99 |
#ifdef ALLOW_DIAGNOSTICS |
100 |
#include "SIZE.h" |
101 |
#include "diagnostics_SIZE.h" |
102 |
#include "diagnostics.h" |
103 |
#endif |
104 |
|
105 |
integer im,jm,nlay,istrip,nymd,nhms,bi,bj,ndturb |
106 |
integer ntracers, ptracers |
107 |
integer nchp,nchptot,nchplnd |
108 |
_RL ptop |
109 |
_RL pz(im,jm),uz(im,jm,nlay),vz(im,jm,nlay),tz(im,jm,nlay) |
110 |
_RL qz(im,jm,nlay,ntracers) |
111 |
_RL plz(im,jm,nlay),plze(im,jm,nlay+1),dpres(im,jm,nlay) |
112 |
_RL pkht(im,jm,nlay+1),pkz(im,jm,nlay) |
113 |
_RL ctmt(nchp),xxmt(nchp),yymt(nchp),zetamt(nchp) |
114 |
_RL xlmt(nchp,nlay),khmt(nchp,nlay),tke(nchp,nlay) |
115 |
_RL tgz(im, jm),fracland(im,jm) |
116 |
integer landtype(im,jm) |
117 |
_RL tcanopy(nchp),tdeep(nchp),ecanopy(nchp),swetshal(nchp) |
118 |
_RL swetroot(nchp),swetdeep(nchp),snodep(nchp),capac(nchp) |
119 |
_RL chfr(nchp),chlt(nchp),chlon(nchp) |
120 |
integer igrd(nchp),ityp(nchp) |
121 |
_RL alai(nchp),agrn(nchp),thkz(im,jm) |
122 |
logical tprof |
123 |
_RL duturb(im,jm,nlay),dvturb(im,jm,nlay) |
124 |
_RL dtturb(im,jm,nlay),dqturb(im,jm,nlay,ntracers) |
125 |
_RL st4(im,jm),dst4(im,jm) |
126 |
_RL radswg(im,jm),radswt(im,jm),radlwg(im,jm) |
127 |
_RL fdifpar(im,jm),fdirpar(im,jm) |
128 |
_RL rainlsp(im,jm),rainconv(im,jm),snowfall(im,jm) |
129 |
_RL tempref (im,jm) |
130 |
integer imstturblw, imstturbsw |
131 |
_RL qliqavesw(im,jm,nlay),qliqavelw(im,jm,nlay) |
132 |
_RL fccavelw (im,jm,nlay),fccavesw (im,jm,nlay) |
133 |
_RL qqgrid (im,jm,nlay) |
134 |
integer myid |
135 |
|
136 |
C Local Variables |
137 |
|
138 |
integer numstrips |
139 |
integer ijall |
140 |
_RL fmu,hice,tref,pref,cti,ed |
141 |
C Set fmu and ed to zero for no background diffusion |
142 |
parameter ( fmu = 0.00000 ) |
143 |
parameter ( hice = 300. ) |
144 |
parameter ( tref = 258. ) |
145 |
parameter ( pref = 500. ) |
146 |
parameter ( cti = 0.0052 ) |
147 |
parameter ( ed = 0.0 ) |
148 |
|
149 |
_RL qliqtmp(im,jm,nlay) |
150 |
_RL fcctmp(im,jm,nlay) |
151 |
_RL tmpdiag(im,jm) |
152 |
_RL thtgz(im*jm) |
153 |
_RL tempor1(im,jm,nlay),tempor2(im,jm,nlay),tempor3(im,jm,nlay) |
154 |
_RL tempor4(im,jm,nlay) |
155 |
_RL tempsfc1(im,jm),tempsfc2(im,jm),tempsfc3(im,jm) |
156 |
|
157 |
integer nland |
158 |
_RL alwcoeff(nchp),blwcoeff(nchp) |
159 |
_RL netsw(nchp) |
160 |
_RL cnvprec(nchp),lsprec(nchp) |
161 |
_RL snowprec(nchp) |
162 |
_RL pardiff(nchp),pardirct(nchp) |
163 |
_RL pmsc(nchp) |
164 |
_RL netlw(nchp) |
165 |
_RL sqscat(nchp), rsoil1(nchp) |
166 |
_RL rsoil2(nchp) |
167 |
_RL rdc(nchp),u2fac(nchp) |
168 |
_RL z2ch(nchp) |
169 |
_RL zoch(nchp),cdrc(nchp) |
170 |
_RL cdsc(nchp) |
171 |
_RL dqsdt(nchp) |
172 |
_RL tground(nchp),qground(nchp) |
173 |
_RL utility(nchp) |
174 |
_RL qice(nchp) |
175 |
_RL dqice(nchp) |
176 |
|
177 |
_RL dumsc(nchp,nlay),dvmsc(nchp,nlay) |
178 |
_RL dtmsc(nchp,nlay),dqmsc(nchp,nlay,ntracers) |
179 |
|
180 |
_RL shg(nchp),z0(nchp),icethk(nchp) |
181 |
integer water(nchp) |
182 |
|
183 |
_RL lats(istrip),lons(istrip),cosz(istrip),icest(istrip) |
184 |
_RL rainls(istrip),raincon(istrip),newsnow(istrip) |
185 |
_RL pardf(istrip),pardr(istrip),swnet(istrip) |
186 |
_RL hlwdwn(istrip),alwrad(istrip),blwrad(istrip) |
187 |
_RL tmpnlay(istrip) |
188 |
_RL laistrip(istrip),grnstrip(istrip),z2str(istrip),cd(istrip) |
189 |
_RL scatstr(istrip), rs1str(istrip), rs2str(istrip) |
190 |
_RL rdcstr(istrip),u2fstr(istrip),dqsdtstr(istrip) |
191 |
_RL eturb(istrip),dedqa(istrip),dedtc(istrip) |
192 |
_RL hsturb(istrip),dhsdqa(istrip),dhsdtc(istrip) |
193 |
_RL savetc(istrip),saveqa(istrip),lwstrip(istrip) |
194 |
_RL chfrstr(istrip),psurf(istrip),shgstr(istrip) |
195 |
integer types(istrip),igrdstr(istrip) |
196 |
_RL evap(istrip),shflux(istrip),runoff(istrip),bomb(istrip) |
197 |
_RL eint(istrip),esoi(istrip),eveg(istrip),esno(istrip) |
198 |
_RL smelt(istrip),hlatn(istrip),hlwup(istrip),gdrain(istrip) |
199 |
_RL runsrf(istrip),fwsoil(istrip),evpot(istrip) |
200 |
_RL strdg1(istrip),strdg2(istrip),strdg3(istrip),strdg4(istrip) |
201 |
_RL strdg5(istrip),strdg6(istrip),strdg7(istrip),strdg8(istrip) |
202 |
_RL strdg9(istrip),tmpstrip(istrip),qicestr(istrip) |
203 |
_RL dqicestr(istrip) |
204 |
|
205 |
_RL u(istrip,nlay+1), v(istrip,nlay+1), th(istrip,nlay+1) |
206 |
_RL sh(istrip,nlay+1), thv(istrip,nlay+1), pe(istrip,nlay+1) |
207 |
_RL tracers(istrip,nlay+1,ntracers) |
208 |
_RL dpstr(istrip,nlay),pke(istrip,nlay+1) |
209 |
_RL pk(istrip,nlay), qq(istrip,nlay), p(istrip,nlay) |
210 |
_RL sri(istrip,nlay), skh(istrip,nlay), skm(istrip,nlay) |
211 |
_RL stuflux(istrip,nlay), stvflux(istrip,nlay) |
212 |
_RL sttflux(istrip,nlay), stqflux(istrip,nlay) |
213 |
_RL frqtrb(istrip,nlay-1) |
214 |
_RL dshdthg(istrip,nlay),dthdthg(istrip,nlay) |
215 |
_RL dshdshg(istrip,nlay),dthdshg(istrip,nlay) |
216 |
_RL transth(istrip,nlay), transsh(istrip,nlay) |
217 |
|
218 |
_RL tc(istrip),td(istrip),qa(istrip) |
219 |
_RL swet1(istrip),swet2(istrip),swet3(istrip) |
220 |
_RL capacity(istrip),snowdepth(istrip) |
221 |
_RL stz0(istrip) |
222 |
_RL stdiag(istrip) |
223 |
_RL tends(istrip),sustar(istrip), sz0(istrip),pbldpth(istrip) |
224 |
_RL sct(istrip), scu(istrip), swinds(istrip) |
225 |
_RL stu2m(istrip),stv2m(istrip),stt2m(istrip),stq2m(istrip) |
226 |
_RL stu10m(istrip),stv10m(istrip),stt10m(istrip),stq10m(istrip) |
227 |
integer stwatr(istrip) |
228 |
_RL wspeed(istrip) |
229 |
|
230 |
_RL ctsave(istrip),xxsave(istrip),yysave(istrip) |
231 |
_RL zetasave(istrip) |
232 |
_RL xlsave(istrip,nlay),khsave(istrip,nlay) |
233 |
_RL qliq(istrip,nlay),turbfcc(istrip,nlay) |
234 |
_RL qliqmsc(nchp,nlay),fccmsc(nchp,nlay) |
235 |
|
236 |
integer ndlsm |
237 |
parameter ( ndlsm = 1) |
238 |
_RL qdiaglsm(nchp,ndlsm) |
239 |
|
240 |
_RL pi,secday,sdayopi2,rgas,akap,cp,alhl |
241 |
_RL faceps,grav,caltoj,virtcon,getcon |
242 |
_RL heatw,undef,timstp,delttrb,dttrb,ra |
243 |
_RL edle,rmu,cltj10,atimstp,tice,const |
244 |
integer istnp1,istnlay,itrtrb,i,j,L,nn,nt |
245 |
integer nocean, nice |
246 |
integer ndmoist,time_left,ndum |
247 |
integer ntracedim |
248 |
_RL dtfac,timstp2,sum0 |
249 |
C logical begin flag - set to true to indicate a cold start |
250 |
logical qbeg |
251 |
|
252 |
integer n,nsecf,nmonf,ndayf |
253 |
nsecf(n) = n/10000*3600 + mod(n,10000)/100* 60 + mod(n,100) |
254 |
nmonf(n) = mod(n,10000)/100 |
255 |
ndayf(n) = mod(n,100) |
256 |
|
257 |
#ifdef CRAY |
258 |
#ifdef f77 |
259 |
cfpp$ expand (qsat) |
260 |
#endif |
261 |
#endif |
262 |
|
263 |
c compute variables that do not change |
264 |
c |
265 |
|
266 |
pi = 4.*atan(1.) |
267 |
secday = getcon('SDAY') |
268 |
sdayopi2 = getcon('SDAY') / (pi*2.) |
269 |
rgas = getcon('RGAS') |
270 |
akap = getcon('KAPPA') |
271 |
cp = getcon('CP') |
272 |
alhl = getcon('LATENT HEAT COND') |
273 |
faceps = getcon('EPSFAC') |
274 |
grav = getcon('GRAVITY') |
275 |
caltoj = getcon('CALTOJ') |
276 |
virtcon = getcon('VIRTCON') |
277 |
heatw = getcon('HEATW') |
278 |
undef = getcon('UNDEF') |
279 |
ntracedim= max(ntracers-ptracers,1) |
280 |
|
281 |
call get_alarm ( 'moist',ndum,ndum,ndmoist,time_left ) |
282 |
timstp = nsecf(ndturb) |
283 |
timstp2 = nsecf(ndmoist) |
284 |
dtfac = min( 1.0, timstp/timstp2 ) |
285 |
|
286 |
c delttrb is the internal turbulence time step |
287 |
c a value equal to ndturb means one internal iteration |
288 |
delttrb = nsecf(ndturb) |
289 |
|
290 |
ijall = im * jm |
291 |
istnp1 = istrip * (nlay+1) |
292 |
istnlay = istrip * nlay |
293 |
itrtrb = ( timstp / delttrb ) + 0.1 |
294 |
dttrb = timstp / float(itrtrb) |
295 |
edle = ed * 0.2 |
296 |
|
297 |
c coefficient of viscosity (background momentum diffusion) |
298 |
c |
299 |
rmu = fmu * tref * rgas / pref |
300 |
cltj10 = 10. * caltoj |
301 |
atimstp = 1. / timstp |
302 |
tice = getcon('FREEZING-POINT') |
303 |
|
304 |
c ********************************************************************** |
305 |
c Check for Cold Start (if QQ is zero everywhere) |
306 |
c ********************************************************************** |
307 |
|
308 |
qbeg = .false. |
309 |
|
310 |
sum0 = 0.0 |
311 |
do L=1,nlay |
312 |
do n=1,nchptot |
313 |
sum0 = sum0 + tke(n,L) |
314 |
enddo |
315 |
enddo |
316 |
|
317 |
#ifdef ALLOW_USE_MPI |
318 |
call mpi_allreduce(sum0,const,1,mpi_double_precision,mpi_sum, |
319 |
. mpi_comm_world,n) |
320 |
#else |
321 |
const = sum0 |
322 |
#endif |
323 |
|
324 |
if( const.eq.0.0 ) then |
325 |
qbeg = .true. |
326 |
if( myid.eq.1 .and. bi.eq.1 ) then |
327 |
print * |
328 |
print *, 'Warning!' |
329 |
print *, 'Turbulent Kinetic Energy has not been initialized.' |
330 |
print *, 'Cold-Start will use Level 2.0 Turbulence.' |
331 |
print * |
332 |
endif |
333 |
endif |
334 |
|
335 |
if(itground.gt.0) then |
336 |
do j =1,jm |
337 |
do i =1,im |
338 |
qdiag(i,j,itground,bi,bj) = qdiag(i,j,itground,bi,bj) + tgz(i,j) |
339 |
enddo |
340 |
enddo |
341 |
endif |
342 |
|
343 |
c ********************************************************************** |
344 |
c Initialization |
345 |
c ********************************************************************** |
346 |
|
347 |
c Initialize diagnostic for ground temperature change |
348 |
c --------------------------------------------------- |
349 |
if(idtg.gt.0) then |
350 |
do j =1,jm |
351 |
do i =1,im |
352 |
qdiag(i,j,idtg,bi,bj) = qdiag(i,j,idtg,bi,bj) - tgz(i,j) |
353 |
enddo |
354 |
enddo |
355 |
endif |
356 |
|
357 |
c ********************************************************************** |
358 |
c entire turbulence and land surface package will run in 'tile space' |
359 |
c do conversion of model state variables to tile space |
360 |
c (ocean points appended to tile space land point arrays) |
361 |
c ********************************************************************** |
362 |
|
363 |
numstrips = ((nchptot-1)/istrip) + 1 |
364 |
|
365 |
call grd2msc(pz(1,1),im,jm,igrd,pmsc,nchp,nchptot) |
366 |
|
367 |
call grd2msc(tgz,im,jm,igrd,tground,nchp,nchptot) |
368 |
do i = 1,ijall |
369 |
tmpdiag(i,1) = st4(i,1) + dst4(i,1)*(tgz(i,1)-tempref(i,1)) |
370 |
1 - dst4(i,1)* tgz(i,1) |
371 |
enddo |
372 |
call grd2msc(tmpdiag,im,jm,igrd,alwcoeff,nchp,nchptot) |
373 |
do i = 1,ijall |
374 |
tmpdiag(i,1) = dst4(i,1) |
375 |
enddo |
376 |
call grd2msc(tmpdiag,im,jm,igrd,blwcoeff,nchp,nchptot) |
377 |
do i = 1,ijall |
378 |
tmpdiag(i,1) = fdifpar(i,1) * radswt(i,1) |
379 |
enddo |
380 |
call grd2msc(tmpdiag,im,jm,igrd,pardiff,nchp,nchptot) |
381 |
do i = 1,ijall |
382 |
tmpdiag(i,1) = fdirpar(i,1) * radswt(i,1) |
383 |
enddo |
384 |
call grd2msc(tmpdiag,im,jm,igrd,pardirct,nchp,nchptot) |
385 |
do i = 1,ijall |
386 |
tmpdiag(i,1) = radswg(i,1) * radswt(i,1) |
387 |
enddo |
388 |
call grd2msc(tmpdiag,im,jm,igrd,netsw,nchp,nchptot) |
389 |
do i = 1,ijall |
390 |
tmpdiag(i,1) = radlwg(i,1) + dst4(i,1)*(tgz(i,1)-tempref(i,1)) |
391 |
enddo |
392 |
call grd2msc(tmpdiag,im,jm,igrd,netlw,nchp,nchptot) |
393 |
call grd2msc(thkz,im,jm,igrd,icethk,nchp,nchptot) |
394 |
call grd2msc(rainlsp,im,jm,igrd,lsprec,nchp,nchptot) |
395 |
call grd2msc(rainconv,im,jm,igrd,cnvprec,nchp,nchptot) |
396 |
call grd2msc(snowfall,im,jm,igrd,snowprec,nchp,nchptot) |
397 |
|
398 |
C Call chpprm to get non-varying vegetation and soil characteristics |
399 |
|
400 |
call chpprm(nymd,nhms,nchp,nchplnd,chlt,ityp,alai, |
401 |
1 agrn,zoch,z2ch,cdrc,cdsc,sqscat,u2fac,rsoil1,rsoil2,rdc) |
402 |
|
403 |
c ********************************************************************** |
404 |
c **** surface specification **** |
405 |
c ********************************************************************** |
406 |
|
407 |
c set water |
408 |
|
409 |
do i = 1,nchptot |
410 |
water(i) = 0 |
411 |
if((ityp(i).eq.100).and.(icethk(i).eq.0. ))water(i) = 1 |
412 |
enddo |
413 |
|
414 |
c roughness length z0 |
415 |
c |
416 |
do i =1,nchptot |
417 |
if (icethk(i).gt.0.) then |
418 |
z0(i) = 1.e-4 |
419 |
else if (ityp(i).eq.100) then |
420 |
z0(i) = 3.e-4 |
421 |
else |
422 |
z0(i) = zoch(i) |
423 |
endif |
424 |
enddo |
425 |
|
426 |
c Fill Array Tground with canopy temperatures over land tiles |
427 |
c (it has sst from the tgz array over the sea ice and ocean tiles) |
428 |
|
429 |
do i = 1,nchplnd |
430 |
tground(i) = tcanopy(i) |
431 |
enddo |
432 |
|
433 |
C value of sh at ground |
434 |
C --------------------- |
435 |
do I =1,nchptot |
436 |
utility(I) = pmsc(i) + ptop |
437 |
call qsat ( tground(i),utility(i),shg(i),dqsdt(i),.true. ) |
438 |
enddo |
439 |
|
440 |
c Fill Array Qground with canopy air specific humidity over land tiles |
441 |
c (it has qstar at tground over the sea ice and ocean tiles) |
442 |
|
443 |
do i = 1,nchplnd |
444 |
qground(i) = ecanopy(i) |
445 |
enddo |
446 |
do i = nchplnd+1,nchptot |
447 |
qground(i) = shg(i) |
448 |
enddo |
449 |
|
450 |
c Fill Array Swetshal with Value 1. over oceans and sea ice |
451 |
do i = nchplnd+1,nchptot |
452 |
swetshal(i) = 1. |
453 |
enddo |
454 |
|
455 |
c compute heat conduction through ice |
456 |
c ----------------------------------- |
457 |
const = ( cti / hice ) * cltj10 |
458 |
do i =1,nchptot |
459 |
qice(i) = 0.0 |
460 |
dqice(i) = 0.0 |
461 |
if( icethk(i).gt.0.0 ) then |
462 |
qice(i) = const*(tice-tground(i)) |
463 |
dqice(i) = -const |
464 |
endif |
465 |
enddo |
466 |
|
467 |
if( iqice.gt.0 ) then |
468 |
do i =1,ijall |
469 |
tmpdiag(i,1) = 0.0 |
470 |
enddo |
471 |
call msc2grd (igrd,chfr,qice,nchp,nchptot,fracland,tmpdiag,im,jm) |
472 |
do j =1,jm |
473 |
do i =1,im |
474 |
qdiag(i,j,iqice,bi,bj) = qdiag(i,j,iqice,bi,bj) + tmpdiag(i,j) |
475 |
enddo |
476 |
enddo |
477 |
nqice = nqice + 1 |
478 |
endif |
479 |
|
480 |
c********************************************************************** |
481 |
c loop over regions |
482 |
c********************************************************************** |
483 |
|
484 |
do 2000 nn = 1, numstrips |
485 |
|
486 |
call strip2tile(uz,igrd,u,nchp,ijall,istrip,nlay,nn) |
487 |
call strip2tile(vz,igrd,v,nchp,ijall,istrip,nlay,nn) |
488 |
call strip2tile(tz,igrd,th,nchp,ijall,istrip,nlay,nn) |
489 |
call strip2tile(qz(1,1,1,1),igrd,sh,nchp,ijall,istrip,nlay,nn) |
490 |
call strip2tile(dpres,igrd,dpstr,nchp,ijall,istrip,nlay,nn) |
491 |
call strip2tile(plz,igrd,p,nchp,ijall,istrip,nlay,nn) |
492 |
call strip2tile(plze,igrd,pe,nchp,ijall,istrip,nlay+1,nn) |
493 |
call strip2tile(pkz,igrd,pk,nchp,ijall,istrip,nlay,nn) |
494 |
call strip2tile(pkht,igrd,pke,nchp,ijall,istrip,nlay+1,nn) |
495 |
c do nt = 1,ntracers-ptracers |
496 |
c call strip2tile(qz(1,1,1,ptracers+nt),igrd,tracers(1,1,nt),nchp, |
497 |
c 1 ijall,istrip,nlay,nn) |
498 |
c enddo |
499 |
|
500 |
call stripit (z0,stz0,nchptot,nchp,istrip,1,nn) |
501 |
call stripit (tground,th(1,nlay+1),nchptot,nchp,istrip,1,nn) |
502 |
call stripit (pmsc,pe(1,nlay+1),nchptot,nchp,istrip,1,nn) |
503 |
call stripit (tke,qq,nchptot,nchp,istrip,nlay-1,nn) |
504 |
call stripit (ctmt,ctsave,nchptot,nchp,istrip,1,nn) |
505 |
call stripit (xxmt,xxsave,nchptot,nchp,istrip,1,nn) |
506 |
call stripit (yymt,yysave,nchptot,nchp,istrip,1,nn) |
507 |
call stripit (zetamt,zetasave,nchptot,nchp,istrip,1,nn) |
508 |
call stripit (xlmt,xlsave,nchptot,nchp,istrip,nlay,nn) |
509 |
call stripit (khmt,khsave,nchptot,nchp,istrip,nlay,nn) |
510 |
call stripitint (water,stwatr,nchptot,nchp,istrip,1,nn) |
511 |
|
512 |
call stripitint (igrd,igrdstr,nchptot,nchp,istrip,1,nn) |
513 |
call stripit (chfr,chfrstr,nchptot,nchp,istrip,1,nn) |
514 |
call stripit (icethk,icest,nchptot,nchp,istrip,1,nn) |
515 |
call stripit (pardiff,pardf,nchptot,nchp,istrip,1,nn) |
516 |
call stripit (pardirct,pardr,nchptot,nchp,istrip,1,nn) |
517 |
call stripit (chlt,lats,nchptot,nchp,istrip,1,nn) |
518 |
call stripit (chlon,lons,nchptot,nchp,istrip,1,nn) |
519 |
call stripit (lsprec,rainls,nchptot,nchp,istrip,1,nn) |
520 |
call stripit (cnvprec,raincon,nchptot,nchp,istrip,1,nn) |
521 |
call stripit (snowprec,newsnow,nchptot,nchp,istrip,1,nn) |
522 |
call stripit (netsw,swnet,nchptot,nchp,istrip,1,nn) |
523 |
call stripit (netlw,lwstrip,nchptot,nchp,istrip,1,nn) |
524 |
call stripit (alwcoeff,alwrad,nchptot,nchp,istrip,1,nn) |
525 |
call stripit (blwcoeff,blwrad,nchptot,nchp,istrip,1,nn) |
526 |
call stripit (alai,laistrip,nchptot,nchp,istrip,1,nn) |
527 |
call stripit (agrn,grnstrip,nchptot,nchp,istrip,1,nn) |
528 |
call stripit (z2ch,z2str,nchptot,nchp,istrip,1,nn) |
529 |
call stripit (sqscat,scatstr,nchptot,nchp,istrip,1,nn) |
530 |
call stripit (rsoil1,rs1str,nchptot,nchp,istrip,1,nn) |
531 |
call stripit (rsoil2,rs2str,nchptot,nchp,istrip,1,nn) |
532 |
call stripit (rdc,rdcstr,nchptot,nchp,istrip,1,nn) |
533 |
call stripit (u2fac,u2fstr,nchptot,nchp,istrip,1,nn) |
534 |
call stripit (shg,shgstr,nchptot,nchp,istrip,1,nn) |
535 |
call stripit (dqsdt,dqsdtstr,nchptot,nchp,istrip,1,nn) |
536 |
call stripit ( qice, qicestr,nchptot,nchp,istrip,1,nn) |
537 |
call stripit (dqice,dqicestr,nchptot,nchp,istrip,1,nn) |
538 |
call stripitint (ityp,types,nchptot,nchp,istrip,1,nn) |
539 |
|
540 |
call stripit (tground,tc,nchptot,nchp,istrip,1,nn) |
541 |
call stripit (tdeep,td,nchptot,nchp,istrip,1,nn) |
542 |
call stripit (qground,qa,nchptot,nchp,istrip,1,nn) |
543 |
call stripit (swetshal,swet1,nchptot,nchp,istrip,1,nn) |
544 |
call stripit (swetroot,swet2,nchptot,nchp,istrip,1,nn) |
545 |
call stripit (swetdeep,swet3,nchptot,nchp,istrip,1,nn) |
546 |
call stripit (snodep,snowdepth,nchptot,nchp,istrip,1,nn) |
547 |
call stripit (capac,capacity,nchptot,nchp,istrip,1,nn) |
548 |
|
549 |
call astro ( nymd,nhms,lats,lons,istrip,cosz,ra ) |
550 |
|
551 |
c we need to count up the land, sea ice and ocean points |
552 |
nocean = 0 |
553 |
nland = 0 |
554 |
nice = 0 |
555 |
do i = 1,istrip |
556 |
if( types(i).lt.100 ) nland = nland + 1 |
557 |
if( types(i).eq.100 ) nocean = nocean + 1 |
558 |
if( types(i).eq.100 .and. icest(i).gt.0.0 ) nice = nice + 1 |
559 |
enddo |
560 |
|
561 |
c Disable following ISTRIP check for MPI version |
562 |
c ---------------------------------------------- |
563 |
c if( (nland+nocean).ne.istrip ) then |
564 |
c print * |
565 |
c print *,'Error!' |
566 |
c print *,'Problem Stripping Land/Ocean/Ice points in Turbulence' |
567 |
c print * |
568 |
c stop |
569 |
c endif |
570 |
|
571 |
c convert temperature of level nlay+1 to theta & value of sh at ground |
572 |
c -------------------------------------------------------------------- |
573 |
do i =1,istrip |
574 |
th(i,nlay+1) = th(i,nlay+1) / pke(i,nlay+1) |
575 |
sh(i,nlay+1) = qa(i) |
576 |
enddo |
577 |
|
578 |
c if(iqg.gt.0) then |
579 |
c do i=1,istrip |
580 |
c tmpstrip(i) = sh(i,nlay+1)*1000 |
581 |
c enddo |
582 |
c call paste2grd(tmpstrip,igrd,chfrstr,istrip,nchp, |
583 |
c 1 qdiag(1,1,iqg,bi,bj),ijall,1,nn,.false.) |
584 |
c endif |
585 |
|
586 |
c value of tracers at the ground |
587 |
c ------------------------------ |
588 |
c do nt = 1,ntracers-ptracers |
589 |
C do i = 1,istrip |
590 |
C tracers(i,nlay+1,nt) = 0. |
591 |
C enddo |
592 |
C enddo |
593 |
|
594 |
c compute virtual potential temperatures |
595 |
c -------------------------------------- |
596 |
do L = 1,nlay+1 |
597 |
do i =1,istrip |
598 |
thv(i,L) = 1. + virtcon * sh(i,L) |
599 |
thv(i,L) = th(i,L) * thv(i,L) |
600 |
enddo |
601 |
enddo |
602 |
do i =1,istrip |
603 |
sh(i,nlay+1) = qa(i) |
604 |
enddo |
605 |
|
606 |
c zero out arrays for output of qliq and fcc |
607 |
do L =1,nlay |
608 |
do i =1,istrip |
609 |
qliq(i,L) = 0. |
610 |
turbfcc(i,L) = 0. |
611 |
enddo |
612 |
enddo |
613 |
|
614 |
c zero out fluxes and derivatives |
615 |
c ------------------------------- |
616 |
do i = 1,istrip |
617 |
eturb(i) = 0. |
618 |
scu(i) = 0. |
619 |
dedqa(i) = 0. |
620 |
dedtc(i) = 0. |
621 |
hsturb(i) = 0. |
622 |
dhsdqa(i) = 0. |
623 |
dhsdtc(i) = 0. |
624 |
enddo |
625 |
|
626 |
c increment diagnostic arrays for quantities calculated before trbfl |
627 |
c ------------------------------------------------------------------ |
628 |
c do i =1,istrip |
629 |
c stdiag(i) = ( thv(i,nlay+1)-thv(i,nlay) ) / pke(i,nlay+1) |
630 |
c enddo |
631 |
c if(idtsrf.gt.0) then |
632 |
c call paste2grd(stdiag,igrd,chfrstr,istrip,nchp, |
633 |
c 1 qdiag(1,1,idtsrf,bi,bj),ijall,1,nn,.false.) |
634 |
c endif |
635 |
|
636 |
|
637 |
if(2.eq.1)then |
638 |
print *,' In turb before trbflx - strip ',nn,' out of ',numstrips |
639 |
print *,' bi = ',bi |
640 |
print *,' ntracers ',ntracers,' ptracers ',ptracers |
641 |
print *,'dttrb,itrtrb,rmu,edle ',dttrb,' ',itrtrb,' ',rmu,' ',edle |
642 |
print *,' nchp ',nchp,' nchptot ',nchptot,' nchplnd ',nchplnd |
643 |
print *,' qbeg, tprof ',qbeg,' ',tprof |
644 |
print *,'istrip,nlay,nymd,nhms ',istrip,' ',nlay,' ',nymd,' ',nhms |
645 |
print *,' grav,cp,rgas,faceps,virtcon,undef ', |
646 |
. grav,' ',cp,' ',rgas,' ',faceps,' ',virtcon,' ',undef |
647 |
print *,' field: th ',th |
648 |
c print *,' field: thv ',thv |
649 |
c print *,' field: sh ',sh |
650 |
c print *,' field: u ',u |
651 |
c print *,' field: v ',v |
652 |
print *,' field: p ',p |
653 |
c print *,' field: pe ',pe |
654 |
c print *,' field: pk ',pk |
655 |
c print *,' field: pke ',pke |
656 |
c print *,' field: dpstr ',dpstr |
657 |
c print *,' field: stwatr ',stwatr |
658 |
c print *,' field: stz0 ',stz0 |
659 |
endif |
660 |
|
661 |
c call trbflx |
662 |
c ----------- |
663 |
call trbflx(nn,th,thv,sh,u,v,qq,p,pe,pk,pke,dpstr,stwatr,stz0, |
664 |
1 tracers,ntracers-ptracers,ntracedim,dttrb,itrtrb,rmu,edle,qbeg, |
665 |
2 tprof,stuflux,stvflux,sri,skh,skm,swinds,sustar,sz0,frqtrb, |
666 |
3 pbldpth,sct,scu,stu2m,stv2m,stt2m,stq2m,stu10m,stv10m,stt10m, |
667 |
4 stq10m,istrip,nlay,nymd,nhms,grav,cp,rgas,faceps,virtcon,undef, |
668 |
5 dshdthg,dshdshg,dthdthg,dthdshg,eturb,dedqa,dedtc, |
669 |
6 hsturb,dhsdqa,dhsdtc,transth,transsh, |
670 |
7 ctsave,xxsave,yysave,zetasave,xlsave,khsave,qliq,turbfcc) |
671 |
|
672 |
|
673 |
if(2.eq.1)then |
674 |
print *,' In turbio, Just after trbflx for strip ',nn,' bi = ',bi |
675 |
print *,' field: stuflux ',stuflux |
676 |
print *,' field: stvflux ',stvflux |
677 |
print *,' field: dshdthg ',dshdthg |
678 |
print *,' field: dshdshg ',dshdshg |
679 |
print *,' field: dthdthg ',dthdthg |
680 |
print *,' field: dthdshg ',dthdshg |
681 |
print *,' field: scu ',scu |
682 |
print *,' field: eturb ',eturb |
683 |
print *,' field: dedqa ',dedqa |
684 |
print *,' field: dedtc ',dedtc |
685 |
print *,' field: hsturb ',hsturb |
686 |
print *,' field: dhsdqa ',dhsdqa |
687 |
print *,' field: dhsdtc ',dhsdtc |
688 |
print *,' field: transth ',transth |
689 |
print *,' field: transsh ',transsh |
690 |
endif |
691 |
|
692 |
call pastit (qq,tke,istrip,nchp,nchptot,nlay,nn) |
693 |
call pastit (ctsave,ctmt,istrip,nchp,nchptot,1,nn) |
694 |
call pastit (xxsave,xxmt,istrip,nchp,nchptot,1,nn) |
695 |
call pastit (yysave,yymt,istrip,nchp,nchptot,1,nn) |
696 |
call pastit (zetasave,zetamt,istrip,nchp,nchptot,1,nn) |
697 |
call pastit (xlsave,xlmt,istrip,nchp,nchptot,nlay,nn) |
698 |
call pastit (khsave,khmt,istrip,nchp,nchptot,nlay,nn) |
699 |
|
700 |
call pastit (qliq ,qliqmsc,istrip,nchp,nchptot,nlay,nn) |
701 |
call pastit (turbfcc,fccmsc,istrip,nchp,nchptot,nlay,nn) |
702 |
|
703 |
c New diagnostic: potential evapotranspiration |
704 |
do i = 1,istrip |
705 |
evpot(i) = transsh(i,nlay) * (shgstr(i) - sh(i,nlay)) |
706 |
enddo |
707 |
|
708 |
C********************************************************************** |
709 |
C Call Land Surface Module |
710 |
C********************************************************************** |
711 |
|
712 |
do i = 1,istrip |
713 |
savetc(i) = tc(i) |
714 |
saveqa(i) = qa(i) |
715 |
enddo |
716 |
do i = 1,istrip |
717 |
cosz(i) = max(cosz(i),0.0001) |
718 |
cd(i) = scu(i)*scu(i) |
719 |
tmpnlay(i) = th(i,nlay)*pk(i,nlay) |
720 |
hlwdwn(i) = alwrad(i)+blwrad(i)*tc(i)-lwstrip(i) |
721 |
psurf(i) = pe(i,nlay+1) |
722 |
wspeed(i) = sqrt(u(i,nlay)*u(i,nlay) + v(i,nlay)*v(i,nlay)) |
723 |
if(wspeed(i) .lt. 1.e-20) wspeed(i) = 1.e-20 |
724 |
C Note: This LSM precip bug needs to be cleaned up |
725 |
ccc newsnow(i) = newsnow(i)*dtfac |
726 |
ccc raincon(i) = raincon(i)*dtfac |
727 |
ccc rainls (i) = rainls (i)*dtfac |
728 |
enddo |
729 |
|
730 |
do i = 1,istrip |
731 |
eturb(i) = eturb(i) * pke(i,nlay+1) |
732 |
dedqa(i) = dedqa(i) * pke(i,nlay+1) |
733 |
hsturb(i) = hsturb(i) * pke(i,nlay+1) |
734 |
enddo |
735 |
|
736 |
do i = 1,istrip |
737 |
strdg1(i) = 0. |
738 |
strdg2(i) = 0. |
739 |
strdg3(i) = 0. |
740 |
strdg4(i) = 0. |
741 |
strdg5(i) = 0. |
742 |
strdg6(i) = 0. |
743 |
strdg7(i) = 0. |
744 |
strdg8(i) = 0. |
745 |
strdg9(i) = 0. |
746 |
bomb(i) = 0. |
747 |
runoff(i) = 0. |
748 |
eint(i) = 0. |
749 |
esoi(i) = 0. |
750 |
eveg(i) = 0. |
751 |
esno(i) = 0. |
752 |
smelt(i) = 0. |
753 |
hlatn(i) = 0. |
754 |
hlwup(i) = 0. |
755 |
gdrain(i) = 0. |
756 |
runsrf(i) = 0. |
757 |
fwsoil(i) = 0. |
758 |
enddo |
759 |
|
760 |
c********************************************************************** |
761 |
c diagnostics: fill arrays for lsm input fields |
762 |
c********************************************************************** |
763 |
c if(isnowfall.gt.0) then |
764 |
c do i = 1,istrip |
765 |
c tmpstrip(i) = newsnow(i)*86400 |
766 |
c enddo |
767 |
c call paste2grd(tmpstrip,igrd,chfrstr,istrip,nchp, |
768 |
c 1 qdiag(1,1,isnowfall,bi,bj),ijall,1,nn,.false.) |
769 |
c endif |
770 |
c if(iraincon.gt.0) then |
771 |
c do i = 1,istrip |
772 |
c tmpstrip(i) = raincon(i)*86400 |
773 |
c enddo |
774 |
c call paste2grd(tmpstrip,igrd,chfrstr,istrip,nchp, |
775 |
c 1 qdiag(1,1,iraincon,bi,bj),ijall,1,nn,.false.) |
776 |
c endif |
777 |
c if(irainlsp.gt.0) then |
778 |
c do i = 1,istrip |
779 |
c tmpstrip(i) = rainls(i)*86400 |
780 |
c enddo |
781 |
c call paste2grd(tmpstrip,igrd,chfrstr,istrip,nchp, |
782 |
c 1 qdiag(1,1,irainlsp,bi,bj),ijall,1,nn,.false.) |
783 |
c endif |
784 |
c if(igreen.gt.0) then |
785 |
c call paste2grd(grnstrip,igrd,chfrstr,istrip,nchp, |
786 |
c 1 qdiag(1,1,igreen,bi,bj),ijall,1,nn,.false.) |
787 |
c endif |
788 |
c if(ilai.gt.0) then |
789 |
c call paste2grd(laistrip,igrd,chfrstr,istrip,nchp, |
790 |
c 1 qdiag(1,1,ilai,bi,bj),ijall,1,nn,.false.) |
791 |
c endif |
792 |
c if(ipardr.gt.0) then |
793 |
c call paste2grd(pardr,igrd,chfrstr,istrip,nchp, |
794 |
c 1 qdiag(1,1,ipardr,bi,bj),ijall,1,nn,.false.) |
795 |
c endif |
796 |
c if(ipardf.gt.0) then |
797 |
c call paste2grd(pardf,igrd,chfrstr,istrip,nchp, |
798 |
c 1 qdiag(1,1,ipardf,bi,bj),ijall,1,nn,.false.) |
799 |
c endif |
800 |
c if(idlwdtc.gt.0) then |
801 |
c call paste2grd(blwrad,igrd,chfrstr,istrip,nchp, |
802 |
c 1 qdiag(1,1,idlwdtc,bi,bj),ijall,1,nn,.false.) |
803 |
c endif |
804 |
c if(idhdtc.gt.0) then |
805 |
c call paste2grd(dhsdtc,igrd,chfrstr,istrip,nchp, |
806 |
c 1 qdiag(1,1,idhdtc,bi,bj),ijall,1,nn,.false.) |
807 |
c endif |
808 |
c if(idedtc.gt.0) then |
809 |
c call paste2grd(dedtc,igrd,chfrstr,istrip,nchp, |
810 |
c 1 qdiag(1,1,idedtc,bi,bj),ijall,1,nn,.false.) |
811 |
c endif |
812 |
c if(idhdqa.gt.0) then |
813 |
c call paste2grd(dhsdqa,igrd,chfrstr,istrip,nchp, |
814 |
c 1 qdiag(1,1,idhdqa,bi,bj),ijall,1,nn,.false.) |
815 |
c endif |
816 |
c if(idedqa.gt.0) then |
817 |
c call paste2grd(dedqa,igrd,chfrstr,istrip,nchp, |
818 |
c 1 qdiag(1,1,idedqa,bi,bj),ijall,1,nn,.false.) |
819 |
c endif |
820 |
c if(ilwgdown.gt.0) then |
821 |
c call paste2grd(hlwdwn,igrd,chfrstr,istrip,nchp, |
822 |
c 1 qdiag(1,1,ilwgdown,bi,bj),ijall,1,nn,.false.) |
823 |
c endif |
824 |
c********************************************************************** |
825 |
|
826 |
if(nland.gt.0)then |
827 |
|
828 |
if(2.eq.1)then |
829 |
print *,' In turbio, Just before tile for strip ',nn,' bi = ',bi |
830 |
print *,' calling tile for ',nland,' land points ' |
831 |
print *,' field: types ',types |
832 |
print *,' field: chfrstr ',chfrstr |
833 |
c print *,' field: rainls ',rainls |
834 |
c print *,' field: newsnow ',newsnow |
835 |
c print *,' field: wspeed ',wspeed |
836 |
print *,' field: eturb ',eturb |
837 |
print *,' field: dedqa ',dedqa |
838 |
print *,' field: dedtc ',dedtc |
839 |
print *,' field: hsturb ',hsturb |
840 |
print *,' field: dhsdqa ',dhsdqa |
841 |
print *,' field: dhsdtc ',dhsdtc |
842 |
c print *,' field: tmpnlay ',tmpnlay |
843 |
c print *,' field: sh(nlay) ',(sh(i,nlay),i=1,istrip) |
844 |
c print *,' field: cd ',cd |
845 |
c print *,' field: cosz ',cosz |
846 |
c print *,' field: pardr ',pardr |
847 |
c print *,' field: pardf ',pardf |
848 |
print *,' field: swnet ',swnet |
849 |
print *,' field: hlwdwn ',hlwdwn |
850 |
c print *,' field: psurf ',psurf |
851 |
c print *,' field: laistrip ',laistrip |
852 |
c print *,' field: grnstrip ',grnstrip |
853 |
c print *,' field: z2str ',z2str |
854 |
c print *,' field: scatstr ',scatstr |
855 |
c print *,' field: z2str ',z2str |
856 |
c print *,' field: rs1str ',rs1str |
857 |
c print *,' field: rs1str ',rs2str |
858 |
c print *,' field: rdcstr ',rdcstr |
859 |
c print *,' field: u2fstr ',u2fstr |
860 |
c print *,' field: dqsdtstr ',dqsdtstr |
861 |
print *,' field: alwrad ',alwrad |
862 |
print *,' field: blwrad ',blwrad |
863 |
print *,' field: tc ',tc |
864 |
print *,' field: td ',td |
865 |
c print *,' field: swet1 ',swet1 |
866 |
c print *,' field: swet2 ',swet2 |
867 |
c print *,' field: swet3 ',swet3 |
868 |
c print *,' field: capacity ',capacity |
869 |
c print *,' field: snowdepth ',snowdepth |
870 |
endif |
871 |
|
872 |
if(isdiag1.gt.0) then |
873 |
call paste2grd(tc,igrd,chfrstr,istrip,nchp, |
874 |
1 tempsfc1,ijall,1,nn,.false.) |
875 |
endif |
876 |
|
877 |
|
878 |
call tile ( |
879 |
I nland, timstp, types, rainls, raincon, newsnow, wspeed, |
880 |
I eturb, dedqa, dedtc, hsturb, dhsdqa, dhsdtc, |
881 |
I tmpnlay, sh(1,nlay), cd, cosz, pardr, pardf, |
882 |
I swnet, hlwdwn, psurf, laistrip, grnstrip, z2str, |
883 |
I scatstr, rs1str, rs2str, rdcstr, u2fstr, |
884 |
I shgstr, dqsdtstr, alwrad, blwrad, |
885 |
U tc, td, qa, swet1, swet2, swet3, capacity, snowdepth, |
886 |
O evap, shflux, runoff, bomb, |
887 |
O eint, esoi, eveg, esno, smelt, hlatn, |
888 |
O hlwup, gdrain, runsrf, fwsoil, |
889 |
O strdg1, strdg2, strdg3, strdg4, |
890 |
O strdg5, strdg6, strdg7, strdg8, strdg9) |
891 |
endif |
892 |
|
893 |
|
894 |
if(isdiag2.gt.0) then |
895 |
call paste2grd(tc,igrd,chfrstr,istrip,nchp, |
896 |
1 tempsfc2,ijall,1,nn,.false.) |
897 |
endif |
898 |
|
899 |
if(2.eq.1)then |
900 |
print *,' In turbio, Just after tile for strip ',nn |
901 |
print *,' calling tile for ',nland,' land points ' |
902 |
print *,' field: tc ',tc |
903 |
c print *,' field: td ',td |
904 |
print *,' field: strdg1 ',strdg1 |
905 |
print *,' field: strdg2 ',strdg2 |
906 |
print *,' field: strdg3 ',strdg3 |
907 |
print *,' field: strdg4 ',strdg4 |
908 |
print *,' field: strdg5 ',strdg5 |
909 |
print *,' field: strdg6 ',strdg6 |
910 |
print *,' field: strdg7 ',strdg7 |
911 |
print *,' field: strdg8 ',strdg8 |
912 |
print *,' field: strdg9 ',strdg9 |
913 |
c print *,' field: swet1 ',swet1 |
914 |
c print *,' field: swet2 ',swet2 |
915 |
c print *,' field: swet3 ',swet3 |
916 |
c print *,' field: capacity ',capacity |
917 |
c print *,' field: snowdepth ',snowdepth |
918 |
endif |
919 |
if( nice.gt.0 ) then |
920 |
print *,' Calling sea ice routine - SHOULD NOT BE HERE!' |
921 |
call seaice ( nocean, timstp, hice, |
922 |
. eturb(nland+1), dedtc(nland+1), |
923 |
. hsturb(nland+1), dhsdtc(nland+1), |
924 |
. qicestr(nland+1), dqicestr(nland+1), |
925 |
. swnet(nland+1), lwstrip(nland+1), blwrad(nland+1), |
926 |
. pke(nland+1,nlay+1), icest(nland+1), |
927 |
. tc(nland+1), qa(nland+1) ) |
928 |
endif |
929 |
|
930 |
c*********************************************************************** |
931 |
c diagnostics: fill arrays for lsm output fields |
932 |
c*********************************************************************** |
933 |
|
934 |
c if(irunoff.gt.0) then |
935 |
c call paste2grd(runoff,igrd,chfrstr,istrip,nchp, |
936 |
c 1 qdiag(1,1,irunoff,bi,bj),ijall,1,nn,.false.) |
937 |
c endif |
938 |
c if(ifwsoil.gt.0) then |
939 |
c call paste2grd(fwsoil,igrd,chfrstr,istrip,nchp, |
940 |
c 1 qdiag(1,1,ifwsoil,bi,bj),ijall,1,nn,.false.) |
941 |
c endif |
942 |
c if(igdrain.gt.0) then |
943 |
c call paste2grd(gdrain,igrd,chfrstr,istrip,nchp, |
944 |
c 1 qdiag(1,1,igdrain,bi,bj),ijall,1,nn,.false.) |
945 |
c endif |
946 |
c if(isnowmelt.gt.0) then |
947 |
c call paste2grd(smelt,igrd,chfrstr,istrip,nchp, |
948 |
c 1 qdiag(1,1,isnowmelt,bi,bj),ijall,1,nn,.false.) |
949 |
c endif |
950 |
c if(ieveg.gt.0) then |
951 |
c call paste2grd(eveg,igrd,chfrstr,istrip,nchp, |
952 |
c 1 qdiag(1,1,ieveg,bi,bj),ijall,1,nn,.false.) |
953 |
c endif |
954 |
c if(iesnow.gt.0) then |
955 |
c call paste2grd(esno,igrd,chfrstr,istrip,nchp, |
956 |
c 1 qdiag(1,1,iesnow,bi,bj),ijall,1,nn,.false.) |
957 |
c endif |
958 |
c if(iesoil.gt.0) then |
959 |
c call paste2grd(esoi,igrd,chfrstr,istrip,nchp, |
960 |
c 1 qdiag(1,1,iesoil,bi,bj),ijall,1,nn,.false.) |
961 |
c endif |
962 |
c if(ieresv.gt.0) then |
963 |
c call paste2grd(eint,igrd,chfrstr,istrip,nchp, |
964 |
c 1 qdiag(1,1,ieresv,bi,bj),ijall,1,nn,.false.) |
965 |
c endif |
966 |
c if(ievpot.gt.0) then |
967 |
c call paste2grd(evpot,igrd,chfrstr,istrip,nchp, |
968 |
c 1 qdiag(1,1,ievpot,bi,bj),ijall,1,nn,.false.) |
969 |
c endif |
970 |
c if(idtc.gt.0) then |
971 |
c call paste2grd(strdg1,igrd,chfrstr,istrip,nchp, |
972 |
c 1 qdiag(1,1,idtc,bi,bj),ijall,1,nn,.false.) |
973 |
c endif |
974 |
c if(idqc.gt.0) then |
975 |
c call paste2grd(strdg2,igrd,chfrstr,istrip,nchp, |
976 |
c 1 qdiag(1,1,idqc,bi,bj),ijall,1,nn,.false.) |
977 |
c endif |
978 |
c if(itcdtc.gt.0) then |
979 |
c call paste2grd(strdg3,igrd,chfrstr,istrip,nchp, |
980 |
c 1 qdiag(1,1,itcdtc,bi,bj),ijall,1,nn,.false.) |
981 |
c endif |
982 |
c if(iraddtc.gt.0) then |
983 |
c call paste2grd(strdg4,igrd,chfrstr,istrip,nchp, |
984 |
c 1 qdiag(1,1,iraddtc,bi,bj),ijall,1,nn,.false.) |
985 |
c endif |
986 |
c if(isensdtc.gt.0) then |
987 |
c call paste2grd(strdg5,igrd,chfrstr,istrip,nchp, |
988 |
c 1 qdiag(1,1,isensdtc,bi,bj),ijall,1,nn,.false.) |
989 |
c endif |
990 |
c if(ilatdtc.gt.0) then |
991 |
c call paste2grd(strdg6,igrd,chfrstr,istrip,nchp, |
992 |
c 1 qdiag(1,1,ilatdtc,bi,bj),ijall,1,nn,.false.) |
993 |
c endif |
994 |
c if(itddtc.gt.0) then |
995 |
c call paste2grd(strdg7,igrd,chfrstr,istrip,nchp, |
996 |
c 1 qdiag(1,1,itddtc,bi,bj),ijall,1,nn,.false.) |
997 |
c endif |
998 |
c if(iqcdtc.gt.0) then |
999 |
c call paste2grd(strdg8,igrd,chfrstr,istrip,nchp, |
1000 |
c 1 qdiag(1,1,iqcdtc,bi,bj),ijall,1,nn,.false.) |
1001 |
c endif |
1002 |
c*********************************************************************** |
1003 |
|
1004 |
if( ndlsm.gt.1 ) then |
1005 |
call pstbitint(types,qdiaglsm(1,1),istrip,nchp,nchptot,1,nn) |
1006 |
call pstbmpit(chfrstr,qdiaglsm(1,2),istrip,nchp,nchptot,1,nn) |
1007 |
call pstbmpit(lats,qdiaglsm(1,3),istrip,nchp,nchptot,1,nn) |
1008 |
call pstbmpit(lons,qdiaglsm(1,4),istrip,nchp,nchptot,1,nn) |
1009 |
c call pstbmpit(igrdstr,qdiaglsm(1,5),istrip,nchp,nchptot,1,nn) |
1010 |
call pstbmpit(tc,qdiaglsm(1,6),istrip,nchp,nchptot,1,nn) |
1011 |
call pstbmpit(td,qdiaglsm(1,7),istrip,nchp,nchptot,1,nn) |
1012 |
call pstbmpit(qa,qdiaglsm(1,8),istrip,nchp,nchptot,1,nn) |
1013 |
call pstbmpit(swet1,qdiaglsm(1,9),istrip,nchp,nchptot,1,nn) |
1014 |
call pstbmpit(swet2,qdiaglsm(1,10),istrip,nchp,nchptot,1,nn) |
1015 |
call pstbmpit(swet3,qdiaglsm(1,11),istrip,nchp,nchptot,1,nn) |
1016 |
call pstbmpit(capacity,qdiaglsm(1,12),istrip,nchp,nchptot,1,nn) |
1017 |
call pstbmpit(snowdepth,qdiaglsm(1,13),istrip,nchp,nchptot,1,nn) |
1018 |
call pstbmpit(eturb,qdiaglsm(1,14),istrip,nchp,nchptot,1,nn) |
1019 |
call pstbmpit(hsturb,qdiaglsm(1,15),istrip,nchp,nchptot,1,nn) |
1020 |
call pstbmpit(cd,qdiaglsm(1,16),istrip,nchp,nchptot,1,nn) |
1021 |
call pstbmpit(laistrip,qdiaglsm(1,17),istrip,nchp,nchptot,1,nn) |
1022 |
call pstbmpit(grnstrip,qdiaglsm(1,18),istrip,nchp,nchptot,1,nn) |
1023 |
call pstbmpit(eint,qdiaglsm(1,19),istrip,nchp,nchptot,1,nn) |
1024 |
call pstbmpit(esoi,qdiaglsm(1,20),istrip,nchp,nchptot,1,nn) |
1025 |
call pstbmpit(eveg,qdiaglsm(1,21),istrip,nchp,nchptot,1,nn) |
1026 |
call pstbmpit(esno,qdiaglsm(1,22),istrip,nchp,nchptot,1,nn) |
1027 |
call pstbmpit(strdg1,qdiaglsm(1,23),istrip,nchp,nchptot,1,nn) |
1028 |
call pstbmpit(strdg2,qdiaglsm(1,24),istrip,nchp,nchptot,1,nn) |
1029 |
call pstbmpit(strdg3,qdiaglsm(1,25),istrip,nchp,nchptot,1,nn) |
1030 |
call pstbmpit(strdg4,qdiaglsm(1,26),istrip,nchp,nchptot,1,nn) |
1031 |
call pstbmpit(strdg5,qdiaglsm(1,27),istrip,nchp,nchptot,1,nn) |
1032 |
call pstbmpit(strdg6,qdiaglsm(1,28),istrip,nchp,nchptot,1,nn) |
1033 |
call pstbmpit(strdg7,qdiaglsm(1,29),istrip,nchp,nchptot,1,nn) |
1034 |
call pstbmpit(strdg8,qdiaglsm(1,30),istrip,nchp,nchptot,1,nn) |
1035 |
call pstbmpit(strdg9,qdiaglsm(1,31),istrip,nchp,nchptot,1,nn) |
1036 |
call pstbmpit(smelt,qdiaglsm(1,32),istrip,nchp,nchptot,1,nn) |
1037 |
call pstbmpit(gdrain,qdiaglsm(1,33),istrip,nchp,nchptot,1,nn) |
1038 |
call pstbmpit(runsrf,qdiaglsm(1,34),istrip,nchp,nchptot,1,nn) |
1039 |
call pstbmpit(fwsoil,qdiaglsm(1,35),istrip,nchp,nchptot,1,nn) |
1040 |
call pstbmpit(evpot,qdiaglsm(1,36),istrip,nchp,nchptot,1,nn) |
1041 |
call pstbmpit(stt2m,qdiaglsm(1,37),istrip,nchp,nchptot,1,nn) |
1042 |
call pstbmpit(stq2m,qdiaglsm(1,38),istrip,nchp,nchptot,1,nn) |
1043 |
endif |
1044 |
|
1045 |
call pastit (tc,tground,istrip,nchp,nchptot,1,nn) |
1046 |
call pastit (td,tdeep,istrip,nchp,nchptot,1,nn) |
1047 |
call pastit (qa,qground,istrip,nchp,nchptot,1,nn) |
1048 |
call pastit (swet1,swetshal,istrip,nchp,nchptot,1,nn) |
1049 |
call pastit (swet2,swetroot,istrip,nchp,nchptot,1,nn) |
1050 |
call pastit (swet3,swetdeep,istrip,nchp,nchptot,1,nn) |
1051 |
call pastit (capacity,capac,istrip,nchp,nchptot,1,nn) |
1052 |
call pastit (snowdepth,snodep,istrip,nchp,nchptot,1,nn) |
1053 |
|
1054 |
c********************************************************************** |
1055 |
c Now update the theta and sh profiles with the new ground temperature |
1056 |
c********************************************************************** |
1057 |
|
1058 |
do i =1,istrip |
1059 |
th(i,nlay+1) = tc(i) / pke(i,nlay+1) |
1060 |
enddo |
1061 |
do L = 1,nlay |
1062 |
do i =1,istrip |
1063 |
th(i,L) = th(i,L) + dthdthg(i,L)*(tc(i)-savetc(i))/pke(i,nlay+1) |
1064 |
enddo |
1065 |
enddo |
1066 |
|
1067 |
do i =1,istrip |
1068 |
sh(i,nlay+1) = qa(i) |
1069 |
enddo |
1070 |
do L = 1,nlay |
1071 |
do i =1,istrip |
1072 |
sh(i,L) = sh(i,L) + dshdshg(i,L)*(qa(i)-saveqa(i)) |
1073 |
enddo |
1074 |
enddo |
1075 |
|
1076 |
do L = 1,nlay |
1077 |
do i =1,istrip |
1078 |
sttflux(i,L) = transth(i,L) * (th(i,L+1)-th(i,L)) |
1079 |
stqflux(i,L) = transsh(i,L) * (sh(i,L+1)-sh(i,L)) |
1080 |
enddo |
1081 |
enddo |
1082 |
|
1083 |
if(2.eq.1)then |
1084 |
print *,' In turbio, just after updating th and sh - strip ',nn |
1085 |
print *,' field: th ',th |
1086 |
print *,' field: sh ',sh |
1087 |
endif |
1088 |
|
1089 |
c tendency updates |
1090 |
c ---------------- |
1091 |
do l=1,nlay |
1092 |
call strip2tile(uz(1,1,l),igrd,tmpstrip,nchp,ijall, |
1093 |
1 istrip,1,nn) |
1094 |
do i =1,istrip |
1095 |
tends(i) = ( u(i,l)-tmpstrip(i) ) |
1096 |
enddo |
1097 |
call pastit (tends,dumsc(1,l),istrip,nchp,nchptot,1,nn) |
1098 |
|
1099 |
call strip2tile(vz(1,1,l),igrd,tmpstrip,nchp,ijall, |
1100 |
1 istrip,1,nn) |
1101 |
do i =1,istrip |
1102 |
tends(i) = ( v(i,l)-tmpstrip(i) ) |
1103 |
enddo |
1104 |
call pastit (tends,dvmsc(1,l),istrip,nchp,nchptot,1,nn) |
1105 |
|
1106 |
call strip2tile(tz(1,1,l),igrd,tmpstrip,nchp,ijall, |
1107 |
1 istrip,1,nn) |
1108 |
do i =1,istrip |
1109 |
tends(i) = ( th(i,l)-tmpstrip(i) ) |
1110 |
enddo |
1111 |
|
1112 |
if(2.eq.1)then |
1113 |
print *,' In turbio, tendencies for strip ',nn,' level ',l |
1114 |
print *,' field: th ',tends |
1115 |
endif |
1116 |
|
1117 |
call pastit (tends,dtmsc(1,l),istrip,nchp,nchptot,1,nn) |
1118 |
|
1119 |
call strip2tile(qz(1,1,l,1),igrd,tmpstrip,nchp,ijall, |
1120 |
1 istrip,1,nn) |
1121 |
do i =1,istrip |
1122 |
tends(i) = ( sh(i,l)-tmpstrip(i) ) |
1123 |
enddo |
1124 |
|
1125 |
if(2.eq.1)then |
1126 |
print *,' In turbio, tendencies for strip ',nn,' level ',l |
1127 |
print *,' field: sh ',tends |
1128 |
endif |
1129 |
|
1130 |
call pastit (tends,dqmsc(1,l,1),istrip,nchp,nchptot,1,nn) |
1131 |
|
1132 |
c do nt = 1,ntracers-ptracers |
1133 |
c call strip2tile(qz(1,1,L,ptracers+nt),igrd,tmpstrip,nchp, |
1134 |
c 1 ijall,istrip,1,nn) |
1135 |
c do i =1,istrip |
1136 |
c tends(i) = ( tracers(i,L,nt)-tmpstrip(i) ) |
1137 |
c enddo |
1138 |
c call pastit(tends,dqmsc(1,L,ptracers+nt),istrip,nchp, |
1139 |
c . nchptot,1,nn) |
1140 |
c enddo |
1141 |
|
1142 |
enddo |
1143 |
|
1144 |
c ********************************************************************* |
1145 |
c **** increment diagnostic arrays for quantities saved in trbflx |
1146 |
c ********************************************************************* |
1147 |
|
1148 |
c note: the order, logic, and scaling of the heat and moisture flux |
1149 |
c diagnostics is critical! |
1150 |
c ------------------------------ |
1151 |
|
1152 |
c if(ievap.gt.0) then |
1153 |
c do i=1,istrip |
1154 |
c tmpstrip(i) = stqflux(i,nlay) * 86400 |
1155 |
c enddo |
1156 |
c call paste2grd(tmpstrip,igrd,chfrstr,istrip,nchp, |
1157 |
c 1 qdiag(1,1,ievap,bi,bj),ijall,1,nn,.false.) |
1158 |
c endif |
1159 |
c if(ieflux.gt.0) then |
1160 |
c do i=1,istrip |
1161 |
c tmpstrip(i) = stqflux(i,nlay) * alhl |
1162 |
c enddo |
1163 |
c call paste2grd(tmpstrip,igrd,chfrstr,istrip,nchp, |
1164 |
c 1 qdiag(1,1,ieflux,bi,bj),ijall,1,nn,.false.) |
1165 |
c endif |
1166 |
c if(ihflux.gt.0) then |
1167 |
c do i=1,istrip |
1168 |
c tmpstrip(i) = sttflux(i,nlay) * cp |
1169 |
c enddo |
1170 |
c call paste2grd(tmpstrip,igrd,chfrstr,istrip,nchp, |
1171 |
c 1 qdiag(1,1,ihflux,bi,bj),ijall,1,nn,.false.) |
1172 |
c endif |
1173 |
c if(ituflux.gt.0) then |
1174 |
c call paste2grd(stuflux,igrd,chfrstr,istrip,nchp, |
1175 |
c 1 qdiag(1,1,ituflux,bi,bj),ijall,nlay,nn,.false.) |
1176 |
c endif |
1177 |
c if(itvflux.gt.0) then |
1178 |
c call paste2grd(stvflux,igrd,chfrstr,istrip,nchp, |
1179 |
c 1 qdiag(1,1,itvflux,bi,bj),ijall,nlay,nn,.false.) |
1180 |
c endif |
1181 |
c if(ittflux.gt.0) then |
1182 |
c do l=1,nlay |
1183 |
c do i=1,istrip |
1184 |
c sttflux(i,l) = sttflux(i,l) * cp |
1185 |
c enddo |
1186 |
c enddo |
1187 |
c call paste2grd(sttflux,igrd,chfrstr,istrip,nchp, |
1188 |
c 1 qdiag(1,1,ittflux,bi,bj),ijall,nlay,nn,.false.) |
1189 |
c endif |
1190 |
c if(itqflux.gt.0) then |
1191 |
c do l=1,nlay |
1192 |
c do i=1,istrip |
1193 |
c stqflux(i,l) = stqflux(i,l) * alhl |
1194 |
c enddo |
1195 |
c enddo |
1196 |
c call paste2grd(stqflux,igrd,chfrstr,istrip,nchp, |
1197 |
c 1 qdiag(1,1,itqflux,bi,bj),ijall,nlay,nn,.false.) |
1198 |
c endif |
1199 |
c if(iri.gt.0) call paste2grd(sri,igrd,chfrstr,istrip,nchp, |
1200 |
c 1 qdiag(1,1,iri,bi,bj),ijall,nlay,nn,.false.) |
1201 |
c if(ikh.gt.0) call paste2grd(skh,igrd,chfrstr,istrip,nchp, |
1202 |
c 1 qdiag(1,1,ikh,bi,bj),ijall,nlay,nn,.false.) |
1203 |
c if(ikm.gt.0) call paste2grd(skm,igrd,chfrstr,istrip,nchp, |
1204 |
c 1 qdiag(1,1,ikm,bi,bj),ijall,nlay,nn,.false.) |
1205 |
c if(ict.gt.0) then |
1206 |
c call paste2grd(sct,igrd,chfrstr,istrip,nchp, |
1207 |
c 1 qdiag(1,1,ict,bi,bj),ijall,1,nn,.false.) |
1208 |
c endif |
1209 |
c if(icu.gt.0) then |
1210 |
c call paste2grd(scu,igrd,chfrstr,istrip,nchp, |
1211 |
c 1 qdiag(1,1,icu,bi,bj),ijall,1,nn,.false.) |
1212 |
c endif |
1213 |
c if(iwinds.gt.0) then |
1214 |
c call paste2grd(swinds,igrd,chfrstr,istrip,nchp, |
1215 |
c 1 qdiag(1,1,iwinds,bi,bj),ijall,1,nn,.false.) |
1216 |
c endif |
1217 |
c if(iuflux.gt.0) then |
1218 |
c call paste2grd(stuflux(1,nlay),igrd,chfrstr,istrip,nchp, |
1219 |
c 1 qdiag(1,1,iuflux,bi,bj),ijall,1,nn,.false.) |
1220 |
c endif |
1221 |
c if(ivflux.gt.0) then |
1222 |
c call paste2grd(stvflux(1,nlay),igrd,chfrstr,istrip,nchp, |
1223 |
c 1 qdiag(1,1,ivflux,bi,bj),ijall,1,nn,.false.) |
1224 |
c endif |
1225 |
c if(iustar.gt.0) then |
1226 |
c call paste2grd(sustar,igrd,chfrstr,istrip,nchp, |
1227 |
c 1 qdiag(1,1,iustar,bi,bj),ijall,1,nn,.false.) |
1228 |
c endif |
1229 |
c if(iz0.gt.0) then |
1230 |
c call paste2grd(sz0,igrd,chfrstr,istrip,nchp, |
1231 |
c 1 qdiag(1,1,iz0,bi,bj),ijall,1,nn,.false.) |
1232 |
c endif |
1233 |
c if(ifrqtrb.gt.0) then |
1234 |
c call paste2grd(frqtrb,igrd,chfrstr,istrip,nchp, |
1235 |
c 1 qdiag(1,1,ifrqtrb,bi,bj),ijall,1,nn,.false.) |
1236 |
c endif |
1237 |
c if(ipbl.gt.0) then |
1238 |
c call paste2grd(pbldpth,igrd,chfrstr,istrip,nchp, |
1239 |
c 1 qdiag(1,1,ipbl,bi,bj),ijall,1,nn,.false.) |
1240 |
c endif |
1241 |
c if(iu2m.gt.0) then |
1242 |
c call paste2grd(stu2m,igrd,chfrstr,istrip,nchp, |
1243 |
c 1 qdiag(1,1,iu2m,bi,bj),ijall,1,nn,.true.) |
1244 |
c endif |
1245 |
c if(iv2m.gt.0) then |
1246 |
c call paste2grd(stv2m,igrd,chfrstr,istrip,nchp, |
1247 |
c 1 qdiag(1,1,iv2m,bi,bj),ijall,1,nn,.true.) |
1248 |
c endif |
1249 |
c if(it2m.gt.0) then |
1250 |
c call paste2grd(stt2m,igrd,chfrstr,istrip,nchp, |
1251 |
c 1 qdiag(1,1,it2m,bi,bj),ijall,1,nn,.true.) |
1252 |
c endif |
1253 |
c if(iq2m.gt.0) then |
1254 |
c do i=1,istrip |
1255 |
c if( stq2m(i).ne.undef ) then |
1256 |
c tmpstrip(i) = stq2m(i) * 1000 |
1257 |
c else |
1258 |
c tmpstrip(i) = undef |
1259 |
c endif |
1260 |
c enddo |
1261 |
c call paste2grd(tmpstrip,igrd,chfrstr,istrip,nchp, |
1262 |
c 1 qdiag(1,1,iq2m,bi,bj),ijall,1,nn,.true.) |
1263 |
c endif |
1264 |
c if(iu10m.gt.0) then |
1265 |
c call paste2grd(stu10m,igrd,chfrstr,istrip,nchp, |
1266 |
c 1 qdiag(1,1,iu10m,bi,bj),ijall,1,nn,.false.) |
1267 |
c endif |
1268 |
c if(iv10m.gt.0) then |
1269 |
c call paste2grd(stv10m,igrd,chfrstr,istrip,nchp, |
1270 |
c 1 qdiag(1,1,iv10m,bi,bj),ijall,1,nn,.false.) |
1271 |
c endif |
1272 |
c if(it10m.gt.0) then |
1273 |
c call paste2grd(stt10m,igrd,chfrstr,istrip,nchp, |
1274 |
c 1 qdiag(1,1,it10m,bi,bj),ijall,1,nn,.false.) |
1275 |
c endif |
1276 |
c if(iq10m.gt.0) then |
1277 |
c do i=1,istrip |
1278 |
c if( stq10m(i).ne.undef ) then |
1279 |
c tmpstrip(i) = stq10m(i) * 1000 |
1280 |
c else |
1281 |
c tmpstrip(i) = undef |
1282 |
c endif |
1283 |
c enddo |
1284 |
c call paste2grd(tmpstrip,igrd,chfrstr,istrip,nchp, |
1285 |
c 1 qdiag(1,1,iq10m,bi,bj),ijall,1,nn,.false.) |
1286 |
c endif |
1287 |
|
1288 |
c********************************************************************** |
1289 |
c more diagnostics: land surface model parameters |
1290 |
c********************************************************************** |
1291 |
|
1292 |
c if(itdeep.gt.0)call paste2grd(td,igrd,chfrstr,istrip,nchp, |
1293 |
c . qdiag(1,1,itdeep,bi,bj),ijall,1,nn,.false.) |
1294 |
c if(iqcanopy .gt.0)call paste2grd(qa,igrd,chfrstr,istrip,nchp, |
1295 |
c . qdiag(1,1,iqcanopy,bi,bj) ,ijall,1,nn,.false.) |
1296 |
c if(ismshal .gt.0)call paste2grd(swet1,igrd,chfrstr,istrip,nchp, |
1297 |
c . qdiag(1,1,ismshal,bi,bj) ,ijall,1,nn,.false.) |
1298 |
c if(ismroot .gt.0)call paste2grd(swet2,igrd,chfrstr,istrip,nchp, |
1299 |
c . qdiag(1,1,ismroot,bi,bj) ,ijall,1,nn,.false.) |
1300 |
c if(ismdeep .gt.0)call paste2grd(swet3,igrd,chfrstr,istrip,nchp, |
1301 |
c . qdiag(1,1,ismdeep,bi,bj) ,ijall,1,nn,.false.) |
1302 |
c if(icapacity.gt.0)call paste2grd(capacity,igrd,chfrstr,istrip, |
1303 |
c . nchp,qdiag(1,1,icapacity,bi,bj),ijall,1,nn,.false.) |
1304 |
c if(isnow.gt.0)call paste2grd(snowdepth,igrd,chfrstr,istrip,nchp, |
1305 |
c . qdiag(1,1,isnow,bi,bj) ,ijall,1,nn,.false.) |
1306 |
|
1307 |
c********************************************************************** |
1308 |
c end regions loop |
1309 |
|
1310 |
2000 continue |
1311 |
|
1312 |
c********************************************************************** |
1313 |
|
1314 |
c increment the counter for the accumulated fcc and qliq arrays |
1315 |
c --------------------------------------------------------------------- |
1316 |
imstturblw = imstturblw + 1 |
1317 |
imstturbsw = imstturbsw + 1 |
1318 |
|
1319 |
c prevent ice or snow from melting |
1320 |
c --------------------------------------------------------------------- |
1321 |
do i =1,nchptot |
1322 |
if( (icethk(i).gt.0.).and.(tground(i).gt.tice) ) tground(i)=tice |
1323 |
enddo |
1324 |
|
1325 |
c Update tcanopy and ecanopy from the land points of the |
1326 |
c tground and qground arrays |
1327 |
c --------------------------------------------------------------------- |
1328 |
do i =1,nchplnd |
1329 |
tcanopy(i) = tground(i) |
1330 |
ecanopy(i) = qground(i) |
1331 |
enddo |
1332 |
|
1333 |
C Initialize Tendencies and Couplings |
1334 |
c ----------------------------------- |
1335 |
do L = 1,nlay |
1336 |
do i = 1,ijall |
1337 |
duturb(i,1,L) = 0. |
1338 |
dvturb(i,1,L) = 0. |
1339 |
dtturb(i,1,L) = 0. |
1340 |
qqgrid(i,1,L) = 0. |
1341 |
qliqtmp(i,1,L) = 0. |
1342 |
fcctmp(i,1,L) = 0. |
1343 |
enddo |
1344 |
do nt = 1,ntracers |
1345 |
do i = 1,ijall |
1346 |
dqturb(i,1,L,nt) = 0. |
1347 |
enddo |
1348 |
enddo |
1349 |
enddo |
1350 |
|
1351 |
C Return Tendencies and Couplings to Grid Space |
1352 |
c --------------------------------------------- |
1353 |
do l = 1,nlay |
1354 |
call msc2grd(igrd,chfr,dumsc(1,L),nchp,nchptot,fracland, |
1355 |
. duturb(1,1,L),im,jm) |
1356 |
call msc2grd(igrd,chfr,dvmsc(1,L),nchp,nchptot,fracland, |
1357 |
. dvturb(1,1,L),im,jm) |
1358 |
call msc2grd(igrd,chfr,dtmsc(1,L),nchp,nchptot,fracland, |
1359 |
. dtturb(1,1,L),im,jm) |
1360 |
do nt = 1,ntracers |
1361 |
call msc2grd(igrd,chfr,dqmsc(1,L,nt),nchp,nchptot,fracland, |
1362 |
. dqturb(1,1,L,nt),im,jm) |
1363 |
enddo |
1364 |
call msc2grd(igrd,chfr, tke(1,L),nchp,nchptot,fracland, |
1365 |
. qqgrid(1,1,L),im,jm) |
1366 |
|
1367 |
call msc2grd(igrd,chfr, fccmsc(1,L),nchp,nchptot,fracland, |
1368 |
. fcctmp(1,1,L),im,jm) |
1369 |
call msc2grd(igrd,chfr,qliqmsc(1,L),nchp,nchptot,fracland, |
1370 |
. qliqtmp(1,1,L),im,jm) |
1371 |
enddo |
1372 |
|
1373 |
c Reduce clouds from conditionally unstable layer |
1374 |
c ----------------------------------------------- |
1375 |
call ctei ( tz,qz,fcctmp,qliqtmp,plz,pkz,pkht,im*jm,nlay ) |
1376 |
|
1377 |
C Bumb Total Cloud Liquid Water and Fraction by Instantanious Values |
1378 |
c ------------------------------------------------------------------ |
1379 |
do l = 1,nlay |
1380 |
do j=1,jm |
1381 |
do i=1,im |
1382 |
fccavesw(i,j,L) = fccavesw(i,j,L) + fcctmp(i,j,L) |
1383 |
fccavelw(i,j,L) = fccavelw(i,j,L) + fcctmp(i,j,L) |
1384 |
qliqavelw(i,j,L) = qliqavelw(i,j,L) + qliqtmp(i,j,L) |
1385 |
qliqavesw(i,j,L) = qliqavesw(i,j,L) + qliqtmp(i,j,L) |
1386 |
enddo |
1387 |
enddo |
1388 |
|
1389 |
if (itrbfcc.gt.0) then |
1390 |
do j=1,jm |
1391 |
do i=1,im |
1392 |
qdiag(i,j,itrbfcc+L-1,bi,bj) = qdiag(i,j,itrbfcc+L-1,bi,bj) + |
1393 |
. fcctmp(i,j,L) |
1394 |
enddo |
1395 |
enddo |
1396 |
endif |
1397 |
|
1398 |
if (itrbqliq.gt.0) then |
1399 |
do j=1,jm |
1400 |
do i=1,im |
1401 |
qdiag(i,j,itrbqliq+L-1,bi,bj)=qdiag(i,j,itrbqliq+L-1,bi,bj)+ |
1402 |
. qliqtmp(i,j,L)*1.e6 |
1403 |
enddo |
1404 |
enddo |
1405 |
endif |
1406 |
enddo |
1407 |
|
1408 |
C********************************************************************** |
1409 |
C And some other variables to be transformed back to grid space: |
1410 |
C Ground Temperature, snow depth and shallow layer ground wetness |
1411 |
do j = 1,jm |
1412 |
do i = 1,im |
1413 |
tgz(i,j) = 0. |
1414 |
enddo |
1415 |
enddo |
1416 |
call msc2grd(igrd,chfr,tground ,nchp,nchptot,fracland,tgz ,im,jm) |
1417 |
|
1418 |
c ********************************************************************* |
1419 |
c **** increment diagnostic array for ground and surface temperatures, |
1420 |
c *** ground temp tendency, and ground humidity |
1421 |
c ********************************************************************* |
1422 |
|
1423 |
c if(itground.gt.0) then |
1424 |
c do j =1,jm |
1425 |
c do i =1,im |
1426 |
c qdiag(i,j,itground,bi,bj) = qdiag(i,j,itground,bi,bj) + tgz(i,j) |
1427 |
c enddo |
1428 |
c enddo |
1429 |
c endif |
1430 |
|
1431 |
if(itcanopy.gt.0) then |
1432 |
do j =1,jm |
1433 |
do i =1,im |
1434 |
qdiag(i,j,itcanopy,bi,bj) = qdiag(i,j,itcanopy,bi,bj) + tgz(i,j) |
1435 |
enddo |
1436 |
enddo |
1437 |
endif |
1438 |
|
1439 |
if(its.gt.0) then |
1440 |
do j =1,jm |
1441 |
do i =1,im |
1442 |
tmpdiag(i,j) = tz(i,j,nlay) * pkht(i,j,nlay) |
1443 |
enddo |
1444 |
enddo |
1445 |
do j =1,jm |
1446 |
do i =1,im |
1447 |
qdiag(i,j,its,bi,bj) = qdiag(i,j,its,bi,bj) + tmpdiag(i,j) |
1448 |
enddo |
1449 |
enddo |
1450 |
endif |
1451 |
|
1452 |
if(idtg.gt.0) then |
1453 |
do j =1,jm |
1454 |
do i =1,im |
1455 |
qdiag(i,j,idtg,bi,bj) = qdiag(i,j,idtg,bi,bj) + tgz(i,j) |
1456 |
enddo |
1457 |
enddo |
1458 |
endif |
1459 |
|
1460 |
c ********************************************************************* |
1461 |
c **** increment diagnostic arrays for tendencies **** |
1462 |
c ********************************************************************* |
1463 |
do L = 1,nlay |
1464 |
|
1465 |
if(iturbu.gt.0) then |
1466 |
do j =1,jm |
1467 |
do i =1,im |
1468 |
qdiag(i,j,iturbu+l-1,bi,bj) = qdiag(i,j,iturbu+l-1,bi,bj) |
1469 |
. + duturb(i,j,l) * atimstp * secday |
1470 |
enddo |
1471 |
enddo |
1472 |
endif |
1473 |
|
1474 |
if(iturbv.gt.0) then |
1475 |
do j =1,jm |
1476 |
do i =1,im |
1477 |
qdiag(i,j,iturbv+l-1,bi,bj) = qdiag(i,j,iturbv+l-1,bi,bj) |
1478 |
. + dvturb(i,j,l) * atimstp * secday |
1479 |
enddo |
1480 |
enddo |
1481 |
endif |
1482 |
|
1483 |
if(iturbq.gt.0) then |
1484 |
do j =1,jm |
1485 |
do i =1,im |
1486 |
qdiag(i,j,iturbq+l-1,bi,bj) = qdiag(i,j,iturbq+l-1,bi,bj) |
1487 |
. + dqturb(i,j,l,1) * atimstp * secday * 1000 |
1488 |
enddo |
1489 |
enddo |
1490 |
endif |
1491 |
|
1492 |
if(iturbt.gt.0) then |
1493 |
do j =1,jm |
1494 |
do i =1,im |
1495 |
qdiag(i,j,iturbt+l-1,bi,bj) = qdiag(i,j,iturbt+l-1,bi,bj) |
1496 |
. + dtturb(i,j,l) * pkz(i,j,l)*atimstp*secday |
1497 |
enddo |
1498 |
enddo |
1499 |
endif |
1500 |
|
1501 |
enddo |
1502 |
|
1503 |
if(isdiag1.gt.0) then |
1504 |
do j =1,jm |
1505 |
do i =1,im |
1506 |
qdiag(i,j,isdiag1,bi,bj) = qdiag(i,j,isdiag1,bi,bj) |
1507 |
. + tempsfc1(i,j) |
1508 |
enddo |
1509 |
enddo |
1510 |
endif |
1511 |
|
1512 |
if(isdiag2.gt.0) then |
1513 |
do j =1,jm |
1514 |
do i =1,im |
1515 |
qdiag(i,j,isdiag2,bi,bj) = qdiag(i,j,isdiag2,bi,bj) |
1516 |
. + tempsfc2(i,j) |
1517 |
enddo |
1518 |
enddo |
1519 |
endif |
1520 |
|
1521 |
c pi-weight the theta and moisture tendencies |
1522 |
c ------------------------------------------- |
1523 |
do i =1,ijall |
1524 |
thtgz(i) = pz(i,1) * atimstp |
1525 |
enddo |
1526 |
do l =1,nlay |
1527 |
do i =1,ijall |
1528 |
duturb(i,1,l) = duturb(i,1,l)*atimstp |
1529 |
dvturb(i,1,l) = dvturb(i,1,l)*atimstp |
1530 |
dtturb(i,1,l) = dtturb(i,1,l)*thtgz(i) |
1531 |
enddo |
1532 |
do nt = 1,ntracers |
1533 |
do i =1,ijall |
1534 |
dqturb(i,1,l,nt) = dqturb(i,1,l,nt)*thtgz(i) |
1535 |
enddo |
1536 |
enddo |
1537 |
enddo |
1538 |
|
1539 |
c ********************************************************************* |
1540 |
c **** zero out the accumulating rainfall and snowfall arrays *** |
1541 |
c ********************************************************************* |
1542 |
|
1543 |
if( time_left.lt.timstp ) then |
1544 |
do j = 1,jm |
1545 |
do i = 1,im |
1546 |
rainlsp(i,j) = 0. |
1547 |
rainconv(i,j) = 0. |
1548 |
snowfall(i,j) = 0. |
1549 |
enddo |
1550 |
enddo |
1551 |
endif |
1552 |
|
1553 |
c ********************************************************************* |
1554 |
c **** bump diagnostic counters *** |
1555 |
c ********************************************************************* |
1556 |
|
1557 |
#ifdef ALLOW_DIAGNOSTICS |
1558 |
if( (bi.eq.1) .and. (bj.eq.1) ) then |
1559 |
nturbt = nturbt + 1 |
1560 |
nturbq = nturbq + 1 |
1561 |
nturbu = nturbu + 1 |
1562 |
nturbv = nturbv + 1 |
1563 |
ntuflux = ntuflux + 1 |
1564 |
ntvflux = ntvflux + 1 |
1565 |
nttflux = nttflux + 1 |
1566 |
ntqflux = ntqflux + 1 |
1567 |
nwinds = nwinds + 1 |
1568 |
nkm = nkm + 1 |
1569 |
nkh = nkh + 1 |
1570 |
nri = nri + 1 |
1571 |
nct = nct + 1 |
1572 |
ncu = ncu + 1 |
1573 |
ntground = ntground + 1 |
1574 |
nts = nts + 1 |
1575 |
ndtg = ndtg + 1 |
1576 |
nqg = nqg + 1 |
1577 |
nqs = nqs + 1 |
1578 |
nhflux = nhflux + 1 |
1579 |
neflux = neflux + 1 |
1580 |
nevap = nevap + 1 |
1581 |
nuflux = nuflux + 1 |
1582 |
nvflux = nvflux + 1 |
1583 |
ndtsrf = ndtsrf + 1 |
1584 |
nustar = nustar + 1 |
1585 |
nz0 = nz0 + 1 |
1586 |
nfrqtrb = nfrqtrb + 1 |
1587 |
npbl = npbl + 1 |
1588 |
nu2m = nu2m + 1 |
1589 |
nv2m = nv2m + 1 |
1590 |
nt2m = nt2m + 1 |
1591 |
nq2m = nq2m + 1 |
1592 |
nu10m = nu10m + 1 |
1593 |
nv10m = nv10m + 1 |
1594 |
nt10m = nt10m + 1 |
1595 |
nq10m = nq10m + 1 |
1596 |
ntcanopy = ntcanopy + 1 |
1597 |
ntdeep = ntdeep + 1 |
1598 |
nqcanopy = nqcanopy + 1 |
1599 |
nsmshal = nsmshal + 1 |
1600 |
nsmroot = nsmroot + 1 |
1601 |
nsmdeep = nsmdeep + 1 |
1602 |
nsnow = nsnow + 1 |
1603 |
ncapacity = ncapacity + 1 |
1604 |
nraincon = nraincon + 1 |
1605 |
nrainlsp = nrainlsp + 1 |
1606 |
nsnowfall = nsnowfall + 1 |
1607 |
nrunoff = nrunoff + 1 |
1608 |
nfwsoil = nfwsoil + 1 |
1609 |
ngdrain = ngdrain + 1 |
1610 |
nsnowmelt = nsnowmelt + 1 |
1611 |
neresv = neresv + 1 |
1612 |
nesoil = nesoil + 1 |
1613 |
neveg = neveg + 1 |
1614 |
nesnow = nesnow + 1 |
1615 |
npardf = npardf + 1 |
1616 |
npardr = npardr + 1 |
1617 |
nlai = nlai + 1 |
1618 |
ngreen = ngreen + 1 |
1619 |
ndlwdtc = ndlwdtc + 1 |
1620 |
ndhdtc = ndhdtc + 1 |
1621 |
ndedtc = ndedtc + 1 |
1622 |
nevpot = nevpot + 1 |
1623 |
nlwgdown = nlwgdown + 1 |
1624 |
ndhdqa = ndhdqa + 1 |
1625 |
ndedqa = ndedqa + 1 |
1626 |
ndtc = ndtc + 1 |
1627 |
ndqc = ndqc + 1 |
1628 |
ntcdtc = ntcdtc + 1 |
1629 |
nraddtc = nraddtc + 1 |
1630 |
nsensdtc = nsensdtc + 1 |
1631 |
nlatdtc = nlatdtc + 1 |
1632 |
ntddtc = ntddtc + 1 |
1633 |
nqcdtc = nqcdtc + 1 |
1634 |
ntrbqliq = ntrbqliq + 1 |
1635 |
ntrbfcc = ntrbfcc + 1 |
1636 |
|
1637 |
nsdiag1 = nsdiag1 + 1 |
1638 |
nsdiag2 = nsdiag2 + 1 |
1639 |
endif |
1640 |
|
1641 |
#endif |
1642 |
|
1643 |
return |
1644 |
end |
1645 |
SUBROUTINE TRBFLX (NN,TH,THV,SH,U,V,QQ,PL,PLE,PLK,PLKE,DPSTR, |
1646 |
1 IWATER,Z0,tracers,ntrace,ntracedim,DTAU,ITRTRB,KMBG,KHBG,QBEG, |
1647 |
2 TPROF,WU,WV,SRI,ET,EU,SWINDS,sustar,sz0,freqdg,pbldpth, |
1648 |
3 sct,scu,stu2m,stv2m,stt2m,stq2m,stu10m,stv10m,stt10m,stq10m, |
1649 |
4 irun,nlev,NYMD,NHMS,grav,cp,rgas,faceps,virtcon,undef, |
1650 |
5 dshdthg,dshdshg,dthdthg,dthdshg,eturb,dedqa,dedtc, |
1651 |
6 hsturb,dhsdqa,dhsdtc,transth,transsh, |
1652 |
7 ctsave,xxsave,yysave,zetasave,xlsave,khsave,qliq,turbfcc) |
1653 |
C********************************************************************** |
1654 |
C SUBROUTINE TRBFLX - COMPUTES TURBULENT ADJUSTMENTS TO ATMOSPHERIC |
1655 |
C PROFILE |
1656 |
C - CALLED FROM PBL DRIVER |
1657 |
C |
1658 |
C ARGUMENTS :: |
1659 |
C |
1660 |
C INPUT: |
1661 |
C ------ |
1662 |
C TH - POTENTIAL TEMPERATURE PROFILE |
1663 |
C THV - VIRTUAL POTENTIAL TEMPERATURE PROFILE |
1664 |
C SH - SPECIFIC HUMIDITY PROFILE |
1665 |
C U - U - COMPONENT OF WIND PROFILE |
1666 |
C V - V - COMPONENT OF WIND PROFILE |
1667 |
C QQ - TURBULENT KINETIC ENERGY |
1668 |
C PL - EVEN LEVEL PRESSURES |
1669 |
C PLE - EDGE LEVEL PRESSURES |
1670 |
C PLK - EVEN LEVEL PRESSURES ** KAPPA |
1671 |
C PLKE - EDGE LEVEL PRESSURES ** KAPPA |
1672 |
C DPSTR - PRESSURE INTERVALS |
1673 |
C WATER - BIT ARRAY - '1' OVER OCEANS |
1674 |
C Z0 - SURFACE ROUGHNESS |
1675 |
C tracers - array of passive tracers |
1676 |
C ntrace - number of tracers to be diffused |
1677 |
C ntracedim - outer dimension of tracers array |
1678 |
C DTAU - TIME CHANGE PER ITERATION OF TRBFLX |
1679 |
C ITRTRB - NUMBER OF ITERATIONS OF TRBFLX |
1680 |
C KMBG - BACKGROUND VALUE OF MOMENTUM TRANSFER COEF |
1681 |
C KHBG - BACKGROUND VALUE OF HEAT TRANSFER COEF |
1682 |
C NLEV - NUMBER OF ATMOSPHERIC LEVELS TO CALCULATE |
1683 |
C QBEG - LOGICAL .TRUE. FOR INITIAL START OF GCM |
1684 |
C TPROF - LOGICAL .TRUE. TO CALCULATE PT BY PT DIAGS |
1685 |
C |
1686 |
C OUTPUT: |
1687 |
C ------- |
1688 |
C PROFILES RETURNED WITH UPDATED VALUES |
1689 |
C |
1690 |
C********************************************************************** |
1691 |
implicit none |
1692 |
|
1693 |
C Argument list declarations |
1694 |
integer nn,irun,nlev,ntrace,ntracedim,itrtrb,nhms,nymd |
1695 |
_RL TH(irun,NLEV+1),THV(irun,NLEV+1),SH(irun,NLEV+1) |
1696 |
_RL U(irun,NLEV+1),V(irun,NLEV+1),QQ(irun,NLEV) |
1697 |
_RL PL(irun,NLEV),PLE(irun,NLEV+1),PLK(irun,NLEV) |
1698 |
_RL PLKE(irun,NLEV+1),DPSTR(irun,NLEV) |
1699 |
integer IWATER(irun) |
1700 |
_RL Z0(irun) |
1701 |
_RL tracers(irun,nlev+1,ntracedim) |
1702 |
_RL dtau,KMBG,KHBG |
1703 |
LOGICAL QBEG,TPROF |
1704 |
_RL SWINDS(irun) |
1705 |
_RL SRI(irun,nlev), ET(irun,nlev) |
1706 |
_RL EU (irun,nlev) |
1707 |
_RL WU(irun,nlev) |
1708 |
_RL WV (irun,nlev), pbldpth(irun) |
1709 |
_RL sustar(irun), sz0(irun) |
1710 |
_RL freqdg(irun,nlev-1) |
1711 |
_RL sct(irun), scu(irun) |
1712 |
_RL stu2m(irun),stv2m(irun),stt2m(irun),stq2m(irun) |
1713 |
_RL stu10m(irun),stv10m(irun),stt10m(irun),stq10m(irun) |
1714 |
_RL grav,cp,rgas,faceps,virtcon,undef |
1715 |
_RL eturb(irun),dedqa(irun),dedtc(irun) |
1716 |
_RL hsturb(irun),dhsdqa(irun),dhsdtc(irun) |
1717 |
_RL dshdthg(irun,nlev),dthdthg(irun,nlev) |
1718 |
_RL dshdshg(irun,nlev),dthdshg(irun,nlev) |
1719 |
_RL transth(irun,nlev),transsh(irun,nlev) |
1720 |
_RL ctsave(irun),xxsave(irun),yysave(irun) |
1721 |
_RL zetasave(irun),xlsave(irun,nlev),khsave(irun,nlev) |
1722 |
_RL qliq(irun,nlev),turbfcc(irun,nlev) |
1723 |
|
1724 |
C Local Variables |
1725 |
_RL b1,b3,alpha,halpha,qqmin,qbustr |
1726 |
PARAMETER ( B1 = 16.6 ) |
1727 |
PARAMETER ( B3 = 1. / B1 ) |
1728 |
PARAMETER ( ALPHA = 0.1 ) |
1729 |
PARAMETER ( HALPHA = ALPHA * 0.5 ) |
1730 |
PARAMETER ( QQMIN = 0.005 ) |
1731 |
PARAMETER ( QBUSTR = 2.550952 ) |
1732 |
_RL argmax, onethrd, z1pem25, b2, two |
1733 |
PARAMETER (ARGMAX = 30.) |
1734 |
PARAMETER (ONETHRD = 1./3. ) |
1735 |
PARAMETER (Z1PEM25 = 1.E-25) |
1736 |
PARAMETER ( B2 = 10.1 ) |
1737 |
PARAMETER ( two = 2.0 ) |
1738 |
|
1739 |
_RL AHS (irun), HS(irun) |
1740 |
_RL XX (irun), YY(irun), CU(irun) |
1741 |
_RL CT(irun), USTAR(irun) |
1742 |
_RL RIB(irun), ZETA(irun), WS(irun) |
1743 |
_RL DTHS(irun), DELTHS(irun) |
1744 |
_RL DTHL(irun), DELTHL(irun) |
1745 |
_RL RIBIN(irun),CUIN(irun) |
1746 |
_RL CTIN(irun),ZETAIN(irun) |
1747 |
_RL USTARIN(irun),RHOSIN(irun),Z0IN(irun) |
1748 |
_RL qqcolmin(irun),qqcolmax(irun),levpbl(irun) |
1749 |
|
1750 |
_RL ADZ1(irun,nlev), DZ1TMP(irun,nlev) |
1751 |
_RL DZ3(irun,nlev), TEMP(irun,nlev) |
1752 |
_RL DV(irun,nlev), DTHV(irun,nlev) |
1753 |
_RL DPK(irun,nlev), STRT(irun,nlev) |
1754 |
_RL DW2(irun,nlev), RI(irun,nlev) |
1755 |
_RL RHOZPK(irun,nlev), Q(irun,nlev) |
1756 |
_RL RIINIT(irun,nlev), DU(irun,nlev) |
1757 |
_RL QQINIT(irun,nlev), RHOKDZ(irun,nlev) |
1758 |
_RL RHODZ2(irun,nlev) |
1759 |
_RL KM(irun,nlev), KH(irun,nlev) |
1760 |
|
1761 |
_RL DELTH (irun,nlev+1), DELSH (irun,nlev+1) |
1762 |
_RL FLXFAC (irun,nlev+1) |
1763 |
_RL FLXFPK (irun,nlev+1) |
1764 |
|
1765 |
_RL ADZ2 (irun,nlev-1), RHODZ1(irun,nlev-1) |
1766 |
_RL VKZE (irun,nlev-1), VKZM (irun,nlev-1) |
1767 |
_RL XL (irun,nlev-1), QXLM (irun,nlev-1) |
1768 |
_RL QQE (irun,nlev-1), QE (irun,nlev-1) |
1769 |
_RL P3 (irun,nlev-1), XQ (irun,nlev-1) |
1770 |
_RL XLDIAG (irun,nlev-1), FLXFCE(irun,nlev-1) |
1771 |
|
1772 |
LOGICAL FIRST,LAST |
1773 |
integer IBITSTB(irun,nlev),INTQ(irun,nlev) |
1774 |
|
1775 |
C arrays for use by moist bouyancy calculation |
1776 |
C ----------------- |
1777 |
_RL TL(irun,NLEV),DTH(irun,NLEV) |
1778 |
_RL DSH(irun,NLEV) |
1779 |
_RL SHL(irun,NLEV) |
1780 |
_RL AA(irun,NLEV),BB(irun,NLEV),SSDEV(irun,NLEV) |
1781 |
_RL ARG(irun,NLEV),XXZETA(irun),QBYU(irun) |
1782 |
_RL SVAR(irun,NLEV),Q1M(irun,NLEV) |
1783 |
_RL FCC(irun,NLEV) |
1784 |
_RL BETAT(irun,NLEV),BETAW(irun,NLEV) |
1785 |
_RL BETAL(irun,NLEV),BETAT1(irun,NLEV) |
1786 |
_RL BETAW1(irun,NLEV),SBAR(irun,NLEV) |
1787 |
_RL SHSAT(irun,NLEV) |
1788 |
|
1789 |
C Some space for variables to be used in called routines |
1790 |
logical LWATER |
1791 |
integer IVBITRIB(irun) |
1792 |
_RL VHZ(irun) |
1793 |
_RL VH0(irun) |
1794 |
_RL VPSIM(irun),VAPSIM(irun) |
1795 |
_RL VPSIG(irun),VPSIHG(irun) |
1796 |
_RL VTEMP(irun),VDZETA(irun) |
1797 |
_RL VDZ0(irun),VDPSIM(irun) |
1798 |
_RL VDPSIH(irun),VZH(irun) |
1799 |
_RL VXX0(irun),VYY0(irun) |
1800 |
_RL VAPSIHG(irun),VRIB1(irun),VWS1(irun) |
1801 |
_RL VPSIH(irun),VZETAL(irun) |
1802 |
_RL VZ0L(irun),VPSIH2(irun) |
1803 |
_RL VX0PSIM(irun),VG(irun),VG0(irun),VR1MG0(irun) |
1804 |
_RL VZ2(irun),VDZSEA(irun),VAZ0(irun),VXNUM1(irun) |
1805 |
_RL VPSIGB2(irun),VDX(irun),VDXPSIM(irun),VDY(irun) |
1806 |
_RL VXNUM2(irun),VDEN(irun),VAWS1(irun),VXNUM3(irun) |
1807 |
_RL VXNUM(irun),VDZETA1(irun),VDZETA2(irun) |
1808 |
_RL VZCOEF2(irun),VZCOEF1(irun),VTEMPLIN(irun) |
1809 |
_RL VDPSIMC(irun),VDPSIHC(irun) |
1810 |
|
1811 |
_RL DZITRP(irun,nlev-1),STBFCN(irun,nlev) |
1812 |
_RL XL0(irun,nlev),Q1(irun,nlev-1) |
1813 |
_RL WRKIT1(irun,nlev-1) |
1814 |
_RL WRKIT2(irun,nlev-1) |
1815 |
_RL WRKIT3(irun,nlev-1) |
1816 |
_RL WRKIT4(irun,nlev-1) |
1817 |
INTEGER INT1(irun,nlev), INT2(irun,nlev-1) |
1818 |
|
1819 |
_RL vrt1con,pi,rsq2pi,p5sr,clh,vk,rvk,aitr,gbycp,fac1,fac2 |
1820 |
_RL getcon,dum,errf |
1821 |
integer istnlv,nlevm1,nlevm2,nlevml,nlevp1,istnm1,istnm2,istnp1 |
1822 |
integer istnml,istnmq,istlmq,nlevmq |
1823 |
integer i,iter,init,n,nt,LL,L,Lp,Lp1,lmin,lminq,lminq1,ibit |
1824 |
|
1825 |
vk = getcon('VON KARMAN') |
1826 |
rvk = 1./vk |
1827 |
AITR = 1. / FLOAT(ITRTRB) |
1828 |
ISTNLV = irun * NLEV |
1829 |
NLEVM1 = NLEV - 1 |
1830 |
NLEVM2 = NLEV - 2 |
1831 |
NLEVP1 = NLEV + 1 |
1832 |
ISTNM1 = irun * NLEVM1 |
1833 |
ISTNM2 = irun * NLEVM2 |
1834 |
ISTNP1 = irun * NLEVP1 |
1835 |
GBYCP = GRAV / CP |
1836 |
|
1837 |
VRT1CON = 1. + VIRTCON |
1838 |
PI = 4. * ATAN(1.) |
1839 |
RSQ2PI = 1./ ((2.*PI)**0.5) |
1840 |
P5SR = 0.5**0.5 |
1841 |
CLH = GETCON('LATENT HEAT COND') / CP |
1842 |
|
1843 |
C SET INITIAL NUMBER OF ITERATIONS OF SFCFLX |
1844 |
C ------------------------------------------ |
1845 |
N = 6 |
1846 |
C DETERMINE IF INITIAL START |
1847 |
C -------------------------- |
1848 |
INIT = 0 |
1849 |
IF(QBEG) INIT = 1 |
1850 |
C SET DIAGNOSTIC LOGICALS AND INITIALIZE DIAGNOSTIC ARRAYS |
1851 |
C -------------------------------------------------------- |
1852 |
do I =1,istnlv |
1853 |
wu(i,1) = 0. |
1854 |
enddo |
1855 |
do I =1,istnlv |
1856 |
wv(i,1) = 0. |
1857 |
enddo |
1858 |
do I =1,istnlv |
1859 |
eu(i,1) = 0. |
1860 |
enddo |
1861 |
do I =1,istnlv |
1862 |
et(i,1) = 0. |
1863 |
enddo |
1864 |
if (tprof) then |
1865 |
DO I =1,ISTNM1 |
1866 |
XLDIAG(I,1) = 0. |
1867 |
enddo |
1868 |
endif |
1869 |
do I =1,irun |
1870 |
wu(i,nlev) = 0. |
1871 |
enddo |
1872 |
do I =1,irun |
1873 |
wv(i,nlev) = 0. |
1874 |
enddo |
1875 |
do I =1,irun |
1876 |
scu(i) = 0. |
1877 |
enddo |
1878 |
do I =1,irun |
1879 |
sct(i) = 0. |
1880 |
enddo |
1881 |
do I =1,irun |
1882 |
pbldpth(i) = 0. |
1883 |
enddo |
1884 |
do I =1,irun |
1885 |
sustar(i) = 0. |
1886 |
enddo |
1887 |
do I =1,irun |
1888 |
sz0(i) = 0. |
1889 |
enddo |
1890 |
do I =1,ISTNM1 |
1891 |
FREQDG(I,1) = 0. |
1892 |
enddo |
1893 |
do I =1,irun |
1894 |
stu2m(i) = 0. |
1895 |
enddo |
1896 |
do I =1,irun |
1897 |
stv2m(i) = 0. |
1898 |
enddo |
1899 |
do I =1,irun |
1900 |
stt2m(i) = 0. |
1901 |
enddo |
1902 |
do I =1,irun |
1903 |
stq2m(i) = 0. |
1904 |
enddo |
1905 |
do I =1,irun |
1906 |
stu10m(i) = 0. |
1907 |
enddo |
1908 |
do I =1,irun |
1909 |
stv10m(i) = 0. |
1910 |
enddo |
1911 |
do I =1,irun |
1912 |
stt10m(i) = 0. |
1913 |
enddo |
1914 |
do I =1,irun |
1915 |
stq10m(i) = 0. |
1916 |
enddo |
1917 |
|
1918 |
IF (INIT.EQ.1) THEN |
1919 |
DO I = 1,ISTNM1 |
1920 |
XLSAVE(I,1) = 0. |
1921 |
KHSAVE(I,1) = 0. |
1922 |
ENDDO |
1923 |
DO I = 1,irun |
1924 |
CTSAVE(I) = 0. |
1925 |
XXSAVE(I) = 0. |
1926 |
YYSAVE(I) = 0. |
1927 |
ZETASAVE(I) = 0. |
1928 |
ENDDO |
1929 |
ENDIF |
1930 |
|
1931 |
C COMPUTE VERTICAL GRID |
1932 |
C --------------------- |
1933 |
DO 9038 I =1,ISTNLV |
1934 |
ADZ1(I,1) = (CP/GRAV)*(PLKE(I,2)-PLKE(I,1)) |
1935 |
ADZ1(I,1) = THV(I,1) * ADZ1(I,1) |
1936 |
DZ1TMP(I,1) = ADZ1(I,1) |
1937 |
9038 CONTINUE |
1938 |
DO 9040 I =1,ISTNM1 |
1939 |
ADZ2(I,1) = 0.5 * (ADZ1(I,1)+ADZ1(I,2)) |
1940 |
9040 CONTINUE |
1941 |
C DEPTH HS OF SURFACE LAYER |
1942 |
C ------------------------- |
1943 |
DO 9042 I =1,irun |
1944 |
HS(I) = 0.5 * ADZ1(I,NLEV) |
1945 |
9042 CONTINUE |
1946 |
C ALPHA * LAYER DEPTHS FOR TRBLEN |
1947 |
C ------------------------------- |
1948 |
DO 9044 I =1,irun |
1949 |
DZ3(I,1) = HALPHA * ADZ1(I,1) |
1950 |
9044 CONTINUE |
1951 |
DO 9046 I =1,ISTNM2 |
1952 |
DZ3(I,2) = ALPHA * ADZ1(I,2) |
1953 |
9046 CONTINUE |
1954 |
DO 9048 I =1,irun |
1955 |
DZ3(I,NLEV) = ALPHA * HS(I) |
1956 |
9048 CONTINUE |
1957 |
|
1958 |
C VK * HEIGHTS AT MID AND EDGE LEVELS |
1959 |
C ----------------------------------- |
1960 |
DO 9050 I =1,ISTNM1 |
1961 |
TEMP(I,2) = VK * ADZ1(I,2) |
1962 |
9050 CONTINUE |
1963 |
DO 9052 I =1,irun |
1964 |
VKZE(I,NLEVM1) = TEMP(I,NLEV) |
1965 |
9052 CONTINUE |
1966 |
DO 100 LL = 2,NLEVM1 |
1967 |
L = NLEV - LL |
1968 |
LP1 = L + 1 |
1969 |
DO 9054 I =1,irun |
1970 |
VKZE(I,L) = VKZE(I,LP1) + TEMP(I,LP1) |
1971 |
9054 CONTINUE |
1972 |
100 CONTINUE |
1973 |
DO 9056 I =1,ISTNM1 |
1974 |
VKZM(I,1) = VKZE(I,1) - 0.5 * TEMP(I,2) |
1975 |
9056 CONTINUE |
1976 |
C COMPUTE RHO BY DZ AT MID AND EDGE LEVELS |
1977 |
C ---------------------------------------- |
1978 |
DO 200 L = 1,NLEVM1 |
1979 |
LP1 = L + 1 |
1980 |
DO 9058 I =1,irun |
1981 |
FAC1 = DPSTR(I,L) / ( DPSTR(I,L) + DPSTR(I,LP1) ) |
1982 |
FAC2 = 1. - FAC1 |
1983 |
RHODZ2(I,L) = FAC1 * THV(I,LP1) |
1984 |
RHODZ2(I,L) = RHODZ2(I,L) + FAC2 * THV(I,L) |
1985 |
9058 CONTINUE |
1986 |
200 CONTINUE |
1987 |
DO 9060 I =1,ISTNM1 |
1988 |
RHODZ2(I,1) = (RGAS*0.01) * RHODZ2(I,1) |
1989 |
TEMP(I,1) = PLKE(I,2) * ADZ2(I,1) |
1990 |
RHODZ2(I,1) = TEMP(I,1) * RHODZ2(I,1) |
1991 |
RHODZ2(I,1) = PLE(I,2) / RHODZ2(I,1) |
1992 |
RHOZPK(I,1) = RHODZ2(I,1) * PLKE(I,2) |
1993 |
RHODZ1(I,1) = (RGAS*0.01) * THV(I,2) |
1994 |
TEMP(I,1) = PLK(I,2) * ADZ1(I,2) |
1995 |
RHODZ1(I,1) = TEMP(I,1) * RHODZ1(I,1) |
1996 |
RHODZ1(I,1) = PL(I,2) / RHODZ1(I,1) |
1997 |
9060 CONTINUE |
1998 |
C COMPUTE FLXFAC FOR LAYERS AND EDGES |
1999 |
C COMPUTE DTG / DT DUE TO RADIATION AND HEAT CONDUCTION THROUGH ICE |
2000 |
C ----------------------------------------------------------------- |
2001 |
DO 9062 I =1,ISTNLV |
2002 |
FLXFPK(I,1) = PLE(I,2) - PLE(I,1) |
2003 |
FLXFPK(I,1) = FLXFPK(I,1) * PLK(I,1) |
2004 |
FLXFPK(I,1) = (GRAV*DTAU*0.01) / FLXFPK(I,1) |
2005 |
9062 CONTINUE |
2006 |
DO 9064 I =1,irun |
2007 |
FLXFPK(I,NLEVP1) = 0. |
2008 |
9064 CONTINUE |
2009 |
DO 9066 I =1,irun |
2010 |
IF (IWATER(I).EQ.0 ) FLXFPK(I,NLEVP1) = 1. / PLKE(I,NLEVP1) |
2011 |
9066 CONTINUE |
2012 |
DO 9068 I =1,ISTNLV |
2013 |
FLXFAC(I,1) = FLXFPK(I,1) * PLK(I,1) |
2014 |
9068 CONTINUE |
2015 |
DO 9070 I =1,irun |
2016 |
FLXFAC(I,NLEVP1) = FLXFPK(I,NLEVP1) |
2017 |
9070 CONTINUE |
2018 |
DO 9074 I =1,irun |
2019 |
FLXFPK(I,NLEVP1) = CP * FLXFPK(I,NLEVP1) |
2020 |
9074 CONTINUE |
2021 |
DO 9076 I =1,ISTNM1 |
2022 |
FLXFCE(I,1) = PL(I,2) - PL(I,1) |
2023 |
9076 CONTINUE |
2024 |
DO 9078 I =1,ISTNM1 |
2025 |
FLXFCE(I,1) = (GRAV*DTAU*0.01) / FLXFCE(I,1) |
2026 |
9078 CONTINUE |
2027 |
C COMPUTE RECIPROCALS OF DZ1, DZ2, HS |
2028 |
C ----------------------------------- |
2029 |
DO 9084 I =1,ISTNLV |
2030 |
ADZ1(I,1) = 1. / ADZ1(I,1) |
2031 |
9084 CONTINUE |
2032 |
DO 9086 I =1,ISTNM1 |
2033 |
ADZ2(I,1) = 1. / ADZ2(I,1) |
2034 |
9086 CONTINUE |
2035 |
DO 9088 I =1,irun |
2036 |
AHS(I) = 1. / HS(I) |
2037 |
9088 CONTINUE |
2038 |
C COMPUTE GRADIENTS OF P**KAPPA |
2039 |
C ----------------------------- |
2040 |
DO 9090 I =1,ISTNM1 |
2041 |
DPK(I,1) = ( PLK(I,2)-PLK(I,1) ) * ADZ2(I,1) |
2042 |
9090 CONTINUE |
2043 |
DO 9092 I =1,irun |
2044 |
DPK(I,NLEV) = GBYCP / THV(I,NLEV) |
2045 |
9092 CONTINUE |
2046 |
C INITIALIZE Q ARRAY |
2047 |
C ------------------ |
2048 |
DO 9094 I =1,ISTNM1 |
2049 |
Q(I,1) = 2. * QQ(I,1) |
2050 |
Q(I,1) = SQRT( Q(I,1) ) |
2051 |
9094 CONTINUE |
2052 |
FIRST = .TRUE. |
2053 |
LAST = .FALSE. |
2054 |
C********************************************************************** |
2055 |
C********************************************************************** |
2056 |
C MAIN LOOP |
2057 |
C |
2058 |
DO 2000 ITER = 1, ITRTRB |
2059 |
C |
2060 |
IF ( ITER .GE. ITRTRB ) LAST = .TRUE. |
2061 |
C |
2062 |
C CODE FOR MOIST BOUNDARY LAYER - NEW CALCULATION OF DTHV |
2063 |
C |
2064 |
IF(ITER.EQ.1) THEN |
2065 |
DO I = 1,irun |
2066 |
CT(I) = CTSAVE(I) |
2067 |
XX(I) = XXSAVE(I) |
2068 |
YY(I) = YYSAVE(I) |
2069 |
ZETA(I) = ZETASAVE(I) |
2070 |
ENDDO |
2071 |
ENDIF |
2072 |
C |
2073 |
DO I = 1,irun |
2074 |
TL(I,NLEV) = TH(I,NLEV)*PLK(I,NLEV) |
2075 |
call qsat ( tl(i,nlev),pl(i,nlev),shsat(i,nlev),dum,.false. ) |
2076 |
ENDDO |
2077 |
|
2078 |
DO I = 1,irun |
2079 |
BB(I,NLEV) = FACEPS*SHSAT(I,NLEV)/(TL(I,NLEV)*TL(I,NLEV)) |
2080 |
AA(I,NLEV) = 1. / (1. + CLH * BB(I,NLEV) ) |
2081 |
BB(I,NLEV) = BB(I,NLEV) * AA(I,NLEV) * plk(I,nlev) |
2082 |
DTH(I,NLEV) = TH(I,NLEV)-TH(I,NLEVP1) |
2083 |
DSH(I,NLEV) = SH(I,NLEV)-SH(I,NLEVP1) |
2084 |
SBAR(I,NLEV) = AA(I,NLEV) * (SH(I,NLEV) - SHSAT(I,NLEV)) |
2085 |
SSDEV(I,NLEV)=CT(I)*(AA(I,NLEV)*DSH(I,NLEV) |
2086 |
1 -BB(I,NLEV)*DTH(I,NLEV)) |
2087 |
XXZETA(I) = XX(I)-ZETA(I) |
2088 |
IF(XXZETA(I).LT.0.1*XX(I)) XXZETA(I)=0.1*XX(I) |
2089 |
IF(XXZETA(I).LE.0.) XXZETA(I)=0.1 |
2090 |
QBYU(I) =QBUSTR * XXZETA(I) ** ONETHRD |
2091 |
SSDEV(I,NLEV) = B2*YY(I)*SSDEV(I,NLEV)*SSDEV(I,NLEV)/QBYU(I) |
2092 |
SVAR(I,NLEV) = SQRT(SSDEV(I,NLEV)) |
2093 |
IF ( SVAR(I,NLEV).LT.Z1PEM25) SVAR(I,NLEV) = Z1PEM25 |
2094 |
Q1M(I,NLEV) = SBAR(I,NLEV) / SVAR(I,NLEV) |
2095 |
FCC(I,NLEV) = (1./2.) * ( 1. + ERRF( P5SR*Q1M(I,NLEV) ) ) |
2096 |
SHL(I,NLEV) = FCC(I,NLEV) * SBAR(I,NLEV) |
2097 |
ARG(I,NLEV) = (1./2.)*Q1M(I,NLEV)*Q1M(I,NLEV) |
2098 |
IF(ARG(I,NLEV).LE.ARGMAX) |
2099 |
1 SHL(I,NLEV) = SHL(I,NLEV)+RSQ2PI*SVAR(I,NLEV)*EXP(-ARG(I,NLEV)) |
2100 |
BETAT(I,NLEV) = 1. + VIRTCON*SH(I,NLEV) - VRT1CON*SHL(I,NLEV) |
2101 |
BETAW(I,NLEV) = VIRTCON * |
2102 |
1 ( TH(I,NLEV) + CLH * SHL(I,NLEV) * (1./plk(i,nlev)) ) |
2103 |
BETAL(I,NLEV) = (1.+VIRTCON*SH(I,NLEV)-TWO*VRT1CON*SHL(I,NLEV)) |
2104 |
1 * (1./plk(i,nlev)) * CLH - VRT1CON * TH(I,NLEV) |
2105 |
BETAT1(I,NLEV) = BETAT(I,NLEV) - BB(I,NLEV)*FCC(I,NLEV) |
2106 |
1 * BETAL(I,NLEV) |
2107 |
BETAW1(I,NLEV) = BETAW(I,NLEV) + AA(I,NLEV) * FCC(I,NLEV) |
2108 |
1 * BETAL(I,NLEV) |
2109 |
DTHV(I,NLEV) = BETAT1(I,NLEV)*DTH(I,NLEV) + |
2110 |
1 BETAW1(I,NLEV)*DSH(I,NLEV) |
2111 |
THV(I,NLEVP1) = THV(I,NLEV) - DTHV(I,NLEV) |
2112 |
ENDDO |
2113 |
|
2114 |
C SURFACE FLUX TRANSFER COEFFICIENTS |
2115 |
C |
2116 |
CALL SFCFLX(NN,U(1,NLEV),V(1,NLEV), |
2117 |
1 THV(1,NLEV), |
2118 |
2 THV(1,NLEVP1),TH(1,NLEV),TH(1,NLEVP1), |
2119 |
3 SH(1,NLEV),SH(1,NLEVP1),PLK(1,NLEV), |
2120 |
4 PLKE(1,NLEVP1),PLE(1,NLEVP1),Z0, |
2121 |
5 IWATER,HS,AHS, |
2122 |
6 FIRST,LAST,N,irun,aitr,RHODZ2(1,NLEV),RHOZPK(1,NLEV), |
2123 |
7 KH(1,NLEV),KM(1,NLEV),USTAR, |
2124 |
8 XX,YY,CU, |
2125 |
9 CT,RIB,ZETA,WS, |
2126 |
1 stu2m,stv2m,stt2m,stq2m,stu10m,stv10m,stt10m,stq10m, |
2127 |
2 cp,rgas,undef, |
2128 |
3 lwater, ivbitrib, |
2129 |
4 VHZ,VPSIM,VAPSIM,VPSIG,VPSIHG,VTEMP,VDZETA,VDZ0,VDPSIM, |
2130 |
5 VDPSIH,VZH,VXX0,VYY0,VAPSIHG,VRIB1,VWS1,VPSIH, |
2131 |
9 VZETAL,VZ0L,VPSIH2,VH0, |
2132 |
1 VX0PSIM,VG,VG0,VR1MG0,VZ2,VDZSEA,VAZ0,VXNUM1,VPSIGB2,VDX, |
2133 |
2 VDXPSIM,VDY,VXNUM2,VDEN,VAWS1,VXNUM3,VXNUM,VDZETA1,VDZETA2, |
2134 |
3 VZCOEF2,VZCOEF1,VTEMPLIN,VDPSIMC,VDPSIHC) |
2135 |
CI |
2136 |
C |
2137 |
N = 1 |
2138 |
C |
2139 |
C SET VALUES OF TURBULENT VELOCITY AND KINETIC ENERGY AT THE GROUND |
2140 |
C |
2141 |
CB |
2142 |
DO 9098 I =1,irun |
2143 |
Q(I,NLEV) = QBUSTR * USTAR(I) |
2144 |
QQ(I,NLEV) = 0.5 * Q(I,NLEV) * Q(I,NLEV) |
2145 |
9098 CONTINUE |
2146 |
CE |
2147 |
C |
2148 |
C GRADIENTS |
2149 |
C --------- |
2150 |
DO 9100 I =1,ISTNM1 |
2151 |
DU(I,1) = ( U(I,1)- U(I,2) ) * ADZ2(I,1) |
2152 |
DV(I,1) = ( V(I,1)- V(I,2) ) * ADZ2(I,1) |
2153 |
9100 CONTINUE |
2154 |
|
2155 |
|
2156 |
C NEW CODE FOR MOIST BOUNDARY LAYER - NEW CALCULATION OF DTHV |
2157 |
C |
2158 |
IF(ITER.EQ.1) THEN |
2159 |
DO I = 1,ISTNM1 |
2160 |
XL(I,1) = XLSAVE(I,1) |
2161 |
ENDDO |
2162 |
ENDIF |
2163 |
C |
2164 |
DO I =1,ISTNM1 |
2165 |
DTH(I,1) = ( TH(I,1)-TH(I,2) ) * ADZ2(I,1) |
2166 |
DSH(I,1) = ( SH(I,1)-SH(I,2) ) * ADZ2(I,1) |
2167 |
TL(I,1) = TH(I,1)*PLK(I,1) |
2168 |
ENDDO |
2169 |
DO LL = 1,NLEVM1 |
2170 |
DO I = 1,irun |
2171 |
call qsat ( tl(i,LL),pl(i,LL),shsat(i,LL),dum,.false. ) |
2172 |
ENDDO |
2173 |
ENDDO |
2174 |
DO I = 1,ISTNM1 |
2175 |
BB(I,1) = FACEPS*SHSAT(I,1)/(TL(I,1)*TL(I,1)) |
2176 |
AA(I,1) = 1. / (1. + CLH * BB(I,1) ) |
2177 |
COMMM BB(I,1) = BB(I,1) * AA(I,1) * plke(I,2) |
2178 |
BB(I,1) = BB(I,1) * AA(I,1) |
2179 |
SBAR(I,1) = AA(I,1) * (SH(I,1) - SHSAT(I,1)) |
2180 |
ENDDO |
2181 |
DO I = 1,irun |
2182 |
COMMM SSDEV(I,1) = XL(I,1)*(AA(I,1)*DSH(I,1)-BB(I,1)*DTH(I,1)) |
2183 |
SSDEV(I,1) = XL(I,1)*(AA(I,1)*DSH(I,1)- |
2184 |
1 BB(I,1)*plke(I,2)*DTH(I,1)) |
2185 |
SSDEV(I,1) = B2 * KHSAVE(I,1) * SSDEV(I,1) * SSDEV(I,1) |
2186 |
SVAR(I,1) = SQRT(SSDEV(I,1)) |
2187 |
IF ( SVAR(I,1).LT.Z1PEM25) SVAR(I,1) = Z1PEM25 |
2188 |
ENDDO |
2189 |
DO I = 1,ISTNM2 |
2190 |
COMMM SSDEV(I,2) = XL(I,1)*(AA(I,2)*DSH(I,1)-BB(I,2)*DTH(I,1)) |
2191 |
SSDEV(I,2) = XL(I,1)*(AA(I,2)*DSH(I,1)- |
2192 |
1 BB(I,2)*plke(I,2)*DTH(I,1)) |
2193 |
SSDEV(I,2) = B2 * KHSAVE(I,1) * SSDEV(I,1) * SSDEV(I,1) |
2194 |
SVAR(I,2) = SQRT(SSDEV(I,2)) |
2195 |
COMMM SSDEV(I,2) = XL(I,2)*(AA(I,2)*DSH(I,2)-BB(I,2)*DTH(I,2)) |
2196 |
SSDEV(I,2) = XL(I,2)*(AA(I,2)*DSH(I,2)- |
2197 |
1 BB(I,2)*plke(I,3)*DTH(I,2)) |
2198 |
SSDEV(I,2) = B2 * KHSAVE(I,2) * SSDEV(I,2) * SSDEV(I,2) |
2199 |
TEMP(I,2) = SQRT(SSDEV(I,2)) |
2200 |
SVAR(I,2) = (1./2.) * (SVAR(I,2) + TEMP(I,2)) |
2201 |
IF ( SVAR(I,2).LT.Z1PEM25) SVAR(I,2) = Z1PEM25 |
2202 |
ENDDO |
2203 |
DO I = 1,ISTNM1 |
2204 |
Q1M(I,1) = SBAR(I,1) / SVAR(I,1) |
2205 |
FCC(I,1) = (1./2.) * ( 1. + ERRF( P5SR*Q1M(I,1) ) ) |
2206 |
SHL(I,1) = FCC(I,1) * SBAR(I,1) |
2207 |
ARG(I,1) = (1./2.)*Q1M(I,1)*Q1M(I,1) |
2208 |
IF(ARG(I,1).LE.ARGMAX) |
2209 |
1 SHL(I,1) = SHL(I,1)+RSQ2PI*SVAR(I,1)*EXP(-ARG(I,1)) |
2210 |
BETAT(I,1) = 1. + VIRTCON * SH(I,1) - VRT1CON * SHL(I,1) |
2211 |
BETAW(I,1) = VIRTCON * |
2212 |
1 ( TH(I,1) + (CLH/plk(I,1)) * SHL(I,1) ) |
2213 |
BETAL(I,1) = ( 1. + VIRTCON*SH(I,1) - TWO*VRT1CON*SHL(I,1) ) |
2214 |
1 * (CLH/plke(I,2)) - VRT1CON * TH(I,1) |
2215 |
COMMM BETAT1(I,1) = BETAT(I,1) - BB(I,1) * FCC(I,1) * BETAL(I,1) |
2216 |
BETAT1(I,1) = BETAT(I,1) - |
2217 |
1 BB(I,1)*plk(i,1) * FCC(I,1) * BETAL(I,1) |
2218 |
BETAW1(I,1) = BETAW(I,1) + AA(I,1) * FCC(I,1) * BETAL(I,1) |
2219 |
ENDDO |
2220 |
DO I = 1,ISTNM1 |
2221 |
DTHV(I,1) = (1./2.)*((BETAT1(I,1)+BETAT1(I,2))*DTH(I,1) |
2222 |
1 + (BETAW1(I,1)+BETAW1(I,2))*DSH(I,1)) |
2223 |
ENDDO |
2224 |
|
2225 |
C GRADIENTS AT THE TOP OF THE SURFACE LAYER |
2226 |
C ----------------------------------------- |
2227 |
DO 9102 I =1,irun |
2228 |
DU(I,NLEV) = CU(I)*XX(I)*AHS(I)*RVK |
2229 |
DV(I,NLEV) = V(I,NLEV) * DU(I,NLEV) |
2230 |
DU(I,NLEV) = U(I,NLEV) * DU(I,NLEV) |
2231 |
DTHV(I,NLEV) = CT(I) * YY(I) * |
2232 |
1 ((THV(I,NLEV)-THV(I,NLEVP1)) * RVK)* AHS(I) |
2233 |
9102 CONTINUE |
2234 |
|
2235 |
C CALCULATE BRUNT-VAISALA FREQUENCIES, SHEARS, RICHARDSON NUMBERS |
2236 |
C --------------------------------------------------------------- |
2237 |
DO 9104 I =1,ISTNLV |
2238 |
STRT(I,1) = CP * DTHV(I,1) * DPK(I,1) |
2239 |
DW2(I,1) = DU(I,1) * DU(I,1) + DV(I,1) * DV(I,1) |
2240 |
IF ( DW2(I,1) .LE. 1.e-4 ) DW2(I,1) = 1.e-4 |
2241 |
RI(I,1) = STRT(I,1) / DW2(I,1) |
2242 |
9104 CONTINUE |
2243 |
C FILL RICHARDSON NUMBER AND SURFACE WIND DIAGNOSTICS |
2244 |
C (THOSE NEEDED FROM FIRST TRBFLX ITERATION) |
2245 |
C --------------------------------------------------- |
2246 |
DO 9106 I =1,ISTNM1 |
2247 |
SRI(I,1) = RI(I,1) |
2248 |
9106 CONTINUE |
2249 |
DO 9108 I =1,irun |
2250 |
SRI(I,NLEV) = RIB(I) |
2251 |
9108 CONTINUE |
2252 |
DO 9110 I =1,irun |
2253 |
SWINDS(I) = WS(I) |
2254 |
9110 CONTINUE |
2255 |
C INITIALIZE KH, KM, QE AND P3 AND ELIMINATE SMALL QQ |
2256 |
C --------------------------------------------------- |
2257 |
DO 9112 I =1,ISTNM1 |
2258 |
KH(I,1) = 0. |
2259 |
KM(I,1) = 0. |
2260 |
QQE(I,1) = 0. |
2261 |
QE(I,1) = 0. |
2262 |
P3(I,1) = 0. |
2263 |
9112 CONTINUE |
2264 |
DO 9414 I = 1,ISTNM1 |
2265 |
IBITSTB(I,1) = 0 |
2266 |
9414 CONTINUE |
2267 |
DO 9314 I = 1,ISTNM1 |
2268 |
IF ( QQ(I,1) .GT. 1.e-8 ) THEN |
2269 |
INTQ(I,1) = 1 |
2270 |
ELSE |
2271 |
INTQ(I,1) = 0 |
2272 |
ENDIF |
2273 |
9314 CONTINUE |
2274 |
DO 9114 I = 1,ISTNM1 |
2275 |
IF ( QQ(I,1).LE.1.e-8 ) THEN |
2276 |
QQ(I,1) = 0. |
2277 |
Q(I,1) = 0. |
2278 |
ENDIF |
2279 |
9114 CONTINUE |
2280 |
C |
2281 |
DO 300 LMINQ = 1,NLEVM1 |
2282 |
IBIT = 0 |
2283 |
DO 9116 I = 1,irun |
2284 |
IF ( QQ(I,LMINQ).GT.1.e-8 ) IBIT = IBIT + 1 |
2285 |
9116 CONTINUE |
2286 |
IF(IBIT.GE.1)GO TO 310 |
2287 |
300 CONTINUE |
2288 |
LMINQ = NLEV-1 |
2289 |
310 CONTINUE |
2290 |
LMINQ = 1 |
2291 |
LMINQ1 = 1 |
2292 |
IF(LMINQ.GT.1)LMINQ1 = LMINQ - 1 |
2293 |
C LENGTH SCALE |
2294 |
C ------------ |
2295 |
CALL TRBLEN(STRT,DW2,DZ3,Q,VKZE,VKZM,DTHV,DPK,DU,DV,XL,QXLM, |
2296 |
1 NLEV,INIT,LMIN,LMINQ,LMINQ1,CP,INT1,INT2, |
2297 |
2 DZITRP,STBFCN,XL0,Q1,WRKIT1,WRKIT2,WRKIT3,WRKIT4,irun) |
2298 |
C QE AND DIMENSIONLESS COEFFS FROM LEVEL 2 MODEL |
2299 |
C ---------------------------------------------- |
2300 |
IF( LMIN .LT. NLEV ) THEN |
2301 |
NLEVML = NLEV - LMIN |
2302 |
CALL TRBL20(RI(1,LMIN),STRT(1,LMIN),DW2(1,LMIN),XL(1,LMIN), |
2303 |
1 KM(1,LMIN),KH(1,LMIN),QE(1,LMIN),QQE(1,LMIN),IBITSTB(1,LMIN), |
2304 |
2 NLEVML,nlev,irun) |
2305 |
ENDIF |
2306 |
C FOR INITIAL START ONLY : USE EQUILIBRIUM MODEL |
2307 |
C ---------------------------------------------- |
2308 |
IF ( INIT .EQ. 1 ) THEN |
2309 |
DO 9180 I =1,ISTNM1 |
2310 |
QQ(I,1) = QQE(I,1) |
2311 |
Q(I,1) = QE(I,1) |
2312 |
9180 CONTINUE |
2313 |
INIT = 2 |
2314 |
CALL TRBLEN(STRT,DW2,DZ3,Q,VKZE,VKZM,DTHV,DPK,DU,DV,XL,QXLM, |
2315 |
1 NLEV,INIT,LMIN,LMINQ,LMINQ1,CP,INT1,INT2, |
2316 |
2 DZITRP,STBFCN,XL0,Q1,WRKIT1,WRKIT2,WRKIT3,WRKIT4,irun) |
2317 |
INIT = 0 |
2318 |
GO TO 550 |
2319 |
ENDIF |
2320 |
C DIMENSIONLESS COEFFS AND P3 (Q LE QE) |
2321 |
C ------------------------------------- |
2322 |
IF( LMIN .LT. NLEV ) THEN |
2323 |
ISTNML = irun * NLEVML |
2324 |
DO 9320 I = 1,ISTNML |
2325 |
IF ( (IBITSTB(I,LMIN).EQ.1) .AND. |
2326 |
1 ( Q(I,LMIN) .LE. QE(I,LMIN) ) ) THEN |
2327 |
IBITSTB(I,LMIN) = 1 |
2328 |
ELSE |
2329 |
IBITSTB(I,LMIN) = 0 |
2330 |
ENDIF |
2331 |
9320 CONTINUE |
2332 |
DO 9220 I = 1,ISTNML |
2333 |
IF(IBITSTB(I,LMIN).EQ.1 ) THEN |
2334 |
TEMP(I,LMIN) = Q(I,LMIN) / QE(I,LMIN) |
2335 |
KH(I,LMIN) = TEMP(I,LMIN) * KH(I,LMIN) |
2336 |
KM(I,LMIN) = TEMP(I,LMIN) * KM(I,LMIN) |
2337 |
ENDIF |
2338 |
TEMP(I,LMIN) = 0.01 * QQE(I,LMIN) |
2339 |
IF((IBITSTB(I,LMIN).EQ.1) .AND. |
2340 |
1 ( QQ(I,LMIN) .LE. TEMP(I,LMIN) )) THEN |
2341 |
QQ(I,LMIN) = TEMP(I,LMIN) |
2342 |
Q(I,LMIN) = 0.1 * QE(I,LMIN) |
2343 |
ENDIF |
2344 |
IF(IBITSTB(I,LMIN).EQ.1 ) P3(I,LMIN) = (2.*B3) * |
2345 |
1 ( QE(I,LMIN) - Q(I,LMIN) ) |
2346 |
9220 CONTINUE |
2347 |
ENDIF |
2348 |
C DIMENSIONLESS COEFFS AND P3 (Q GT QE) |
2349 |
C ------------------------------------- |
2350 |
NLEVML = NLEV - LMINQ |
2351 |
CALL TRBL25(Q(1,LMINQ),XL(1,LMINQ),STRT(1,LMINQ),DW2(1,LMINQ), |
2352 |
1 IBITSTB(1,LMINQ),INTQ(1,LMINQ),KM(1,LMINQ),KH(1,LMINQ), |
2353 |
2 P3(1,LMINQ),NLEVML,nlev,irun) |
2354 |
C CALCULATE SOURCE TERM P3 |
2355 |
C ------------------------ |
2356 |
IF ( LMINQ .LT. LMIN ) THEN |
2357 |
LMIN = LMINQ |
2358 |
ISTNML = irun * ( NLEV - LMIN ) |
2359 |
ENDIF |
2360 |
IF( LMIN .LT. NLEV ) THEN |
2361 |
DO 9122 I =1,ISTNML |
2362 |
P3(I,LMIN) = P3(I,LMIN) * DTAU / XL(I,LMIN) |
2363 |
TEMP(I,LMIN) = QQE(I,LMIN) * P3(I,LMIN) |
2364 |
XQ(I,LMIN) = QQE(I,LMIN) - QQ(I,LMIN) |
2365 |
9122 CONTINUE |
2366 |
DO 9216 I = 1,ISTNML |
2367 |
IF( ( (IBITSTB(I,LMIN).EQ.1) .AND. |
2368 |
1 ( XQ(I,LMIN) .LT. TEMP(I,LMIN) ) ) |
2369 |
2 .OR. |
2370 |
3 ( (IBITSTB(I,LMIN).EQ.0) .AND. |
2371 |
4 ( XQ(I,LMIN) .GT. TEMP(I,LMIN) ) ) ) |
2372 |
5 P3(I,LMIN) = XQ(I,LMIN) / QQE(I,LMIN) |
2373 |
9216 CONTINUE |
2374 |
ENDIF |
2375 |
550 CONTINUE |
2376 |
C DIAGNOSTIC PROFILES : INITIAL RI AND QQ |
2377 |
C --------------------------------------- |
2378 |
IF ( TPROF .AND. FIRST ) THEN |
2379 |
DO 9118 I =1,irun |
2380 |
RIBIN(I) = RIB(I) |
2381 |
CUIN(I) = CU(I) |
2382 |
CTIN(I) = CT(I) |
2383 |
USTARIN(I) = USTAR(I) |
2384 |
RHOSIN(I) = RHODZ2(I,NLEV) |
2385 |
Z0IN(I) = Z0(I) |
2386 |
ZETAIN(I) = ZETA(I) |
2387 |
9118 CONTINUE |
2388 |
DO 9120 I =1,ISTNLV |
2389 |
RIINIT(I,1) = RI(I,1) |
2390 |
QQINIT(I,1) = QQ(I,1) |
2391 |
9120 CONTINUE |
2392 |
ENDIF |
2393 |
C UPDATE TURBULENT KINETIC ENERGY QQ |
2394 |
C ---------------------------------- |
2395 |
NLEVMQ = NLEV - LMINQ1 |
2396 |
ISTNMQ = irun * NLEVMQ |
2397 |
DO 9306 I =1,ISTNMQ |
2398 |
RHOKDZ(I,LMINQ1) = RHODZ1(I,LMINQ1) |
2399 |
1 * QXLM(I,LMINQ1) |
2400 |
9306 CONTINUE |
2401 |
CALL TRBDIF(QQ(1,LMINQ1),P3(1,LMINQ1),RHOKDZ(1,LMINQ1), |
2402 |
1 FLXFCE(1,LMINQ1),DTHS,DELTHS,NLEVMQ,1,1.0 _d -20,irun) |
2403 |
C |
2404 |
C SAVE KH BEFORE ADDING DIMENSIONS FOR USE BY MOIST BOUYANCY CALCULATION |
2405 |
C |
2406 |
DO I = 1,ISTNM1 |
2407 |
KHSAVE(I,1) = KH(I,1) |
2408 |
ENDDO |
2409 |
C |
2410 |
C DIMENSIONAL DIFFUSION COEFFS INCLUDING BACKGROUND AMOUNTS |
2411 |
C |
2412 |
IF(LMINQ1.GT.1)THEN |
2413 |
ISTLMQ = irun * (LMINQ1-1) |
2414 |
CB |
2415 |
DO 9124 I =1,ISTLMQ |
2416 |
KM(I,1) = KMBG |
2417 |
KH(I,1) = KHBG |
2418 |
9124 CONTINUE |
2419 |
CE |
2420 |
ENDIF |
2421 |
C |
2422 |
CB |
2423 |
DO 9126 I =1,ISTNMQ |
2424 |
Q(I,LMINQ1) = 2. * QQ(I,LMINQ1) |
2425 |
Q(I,LMINQ1) = SQRT(Q(I,LMINQ1)) |
2426 |
XQ(I,LMINQ1) = XL(I,LMINQ1) * Q(I,LMINQ1) |
2427 |
KM(I,LMINQ1)=XQ(I,LMINQ1)*KM(I,LMINQ1)+KMBG |
2428 |
KH(I,LMINQ1)=XQ(I,LMINQ1)*KH(I,LMINQ1)+KHBG |
2429 |
9126 CONTINUE |
2430 |
CE |
2431 |
C |
2432 |
C CALCULATE INTERNAL FLUXES AND UPDATE PROGNOSTIC VARIABLES: TH AND S |
2433 |
C |
2434 |
DO 9128 I =1,ISTNLV |
2435 |
TEMP(I,1) = RHOZPK(I,1) * KH(I,1) |
2436 |
9128 CONTINUE |
2437 |
DO 9130 I =1,ISTNLV |
2438 |
DELTH(I,1) = 0. |
2439 |
9130 CONTINUE |
2440 |
DO 9132 I =1,irun |
2441 |
DELTH(I,NLEVP1) = 1. |
2442 |
9132 CONTINUE |
2443 |
CALL TRBDIF(TH,DELTH,TEMP,FLXFPK,DTHS,DELTHS,NLEV,2,0. _d 0,irun) |
2444 |
do i = 1,irun |
2445 |
hsturb(i) = -1.* dths(i) |
2446 |
dhsdtc(i) = -1.* delths(i) |
2447 |
enddo |
2448 |
do L = 1,nlev |
2449 |
do i = 1,irun |
2450 |
dthdthg(i,L) = delth(i,L) |
2451 |
enddo |
2452 |
enddo |
2453 |
do L = 1,nlev |
2454 |
do i = 1,irun |
2455 |
transth(i,L) = temp(i,L) |
2456 |
enddo |
2457 |
enddo |
2458 |
|
2459 |
DO 9134 I =1,ISTNLV |
2460 |
RHOKDZ(I,1) = RHODZ2(I,1) * KH(I,1) |
2461 |
9134 CONTINUE |
2462 |
DO 9138 I =1,ISTNLV |
2463 |
DELSH(I,1) = 0. |
2464 |
9138 CONTINUE |
2465 |
DO 9140 I =1,irun |
2466 |
DELSH(I,NLEVP1) = 1. |
2467 |
9140 CONTINUE |
2468 |
|
2469 |
CALL TRBDIF(SH,DELSH,RHOKDZ,FLXFAC,DTHL,DELTHL,NLEV, |
2470 |
. 2,0. _d 0,irun) |
2471 |
do i = 1,irun |
2472 |
eturb(i) = -1.* dthl(i) |
2473 |
dedqa(i) = -1.* delthl(i) |
2474 |
enddo |
2475 |
do L = 1,nlev |
2476 |
do i = 1,irun |
2477 |
dshdshg(i,L) = delsh(i,L) |
2478 |
enddo |
2479 |
enddo |
2480 |
do L = 1,nlev |
2481 |
do i = 1,irun |
2482 |
transsh(i,L) = rhokdz(i,L) |
2483 |
enddo |
2484 |
enddo |
2485 |
|
2486 |
C |
2487 |
C Update Tracers Due to Turbulent Diffusion |
2488 |
C |
2489 |
do i = 1,irun |
2490 |
rhokdz(i,nlev) = 0.0 |
2491 |
enddo |
2492 |
|
2493 |
c do nt = 1,ntrace |
2494 |
c do i = 1,irun |
2495 |
c tracers(i,nlev+1,nt) = tracers(i,nlev,nt) |
2496 |
c enddo |
2497 |
c CALL TRBDIF(tracers(1,1,nt),DELSH,RHOKDZ,FLXFAC,DTHL,DELTHL, |
2498 |
c . NLEV,4,0. _d 0,irun) |
2499 |
c enddo |
2500 |
C |
2501 |
C CALCULATE INTERNAL FLUXES AND UPDATE PROGNOSTIC VARIABLES: U AND V |
2502 |
C |
2503 |
DO 9172 I =1,ISTNLV |
2504 |
RHOKDZ(I,1) = RHODZ2(I,1) * KM(I,1) |
2505 |
9172 CONTINUE |
2506 |
CALL TRBDIF(U,V,RHOKDZ,FLXFAC,DTHS,DELTHS,NLEV,3,0. _d 0,irun) |
2507 |
C ( FILL DIAGNOSTIC ARRAYS IF REQUIRED ) |
2508 |
DO 9174 I =1,ISTNLV |
2509 |
WU(I,1) = WU(I,1) + RHOKDZ(I,1) * ( U(I,2) - U(I,1) ) |
2510 |
9174 CONTINUE |
2511 |
DO 9176 I =1,ISTNLV |
2512 |
WV(I,1) = WV(I,1) + RHOKDZ(I,1) * ( V(I,2) - V(I,1) ) |
2513 |
9176 CONTINUE |
2514 |
DO 9300 I = 1,ISTNM1 |
2515 |
IF ( QQ(I,1) .GT. QQMIN ) THEN |
2516 |
IBITSTB(I,1) = 1 |
2517 |
ELSE |
2518 |
IBITSTB(I,1) = 0 |
2519 |
ENDIF |
2520 |
IF( IBITSTB(I,1).EQ.1 ) FREQDG(I,1) = FREQDG(I,1) + aitr |
2521 |
9300 CONTINUE |
2522 |
do i = 1,irun |
2523 |
qqcolmin(i) = qq(i,nlev)*0.1 |
2524 |
qqcolmax(i) = qq(i,nlev) |
2525 |
levpbl(i) = nlev |
2526 |
enddo |
2527 |
DO L = nlev-1,1,-1 |
2528 |
DO I = 1,irun |
2529 |
IF ( (qq(i,l).gt.qqcolmax(I)).and.(levpbl(i).eq.nlev))then |
2530 |
qqcolmax(i) = qq(i,l) |
2531 |
qqcolmin(i) = 0.1*qqcolmax(I) |
2532 |
endif |
2533 |
if((qq(i,l).lt.qqcolmin(i)).and.(levpbl(i).eq.nlev)) |
2534 |
1 levpbl(i)=l |
2535 |
enddo |
2536 |
enddo |
2537 |
do i = 1,irun |
2538 |
lp = levpbl(i) |
2539 |
if(lp.lt.nlev)then |
2540 |
pbldpth(I) = pbldpth(I) + ( (PLE(I,nlev+1)-PLE(I,Lp+2)) + |
2541 |
1 ( (ple(i,lp+2)-ple(i,lp+1))*(qq(i,lp+1)-qqcolmin(i)) |
2542 |
2 / (qq(i,lp+1)-qq(i,lp)) ) ) * aitr |
2543 |
else |
2544 |
pbldpth(I) = pbldpth(I) + ( (PLE(I,nlev+1)-PLE(I,2)) + |
2545 |
1 ( (ple(i,2)-ple(i,1))*(qq(i,1)-qqcolmin(i)) |
2546 |
2 / qq(i,1) ) ) * aitr |
2547 |
endif |
2548 |
enddo |
2549 |
do i=1,irun |
2550 |
sustar(i) = sustar(i) + aitr*ustar(i) |
2551 |
enddo |
2552 |
do i=1,irun |
2553 |
sz0(i) = sz0(i) + aitr*z0(i) |
2554 |
enddo |
2555 |
DO I =1,ISTNLV |
2556 |
EU(I,1) = EU(I,1) + AITR*KM(I,1) |
2557 |
enddo |
2558 |
DO I =1,ISTNLV |
2559 |
ET(I,1) = ET(I,1) + AITR*KH(I,1) |
2560 |
enddo |
2561 |
DO I =1,irun |
2562 |
scu(I) = scu(I) + AITR*cu(I) |
2563 |
enddo |
2564 |
DO I =1,irun |
2565 |
sct(I) = sct(I) + AITR*ct(I) |
2566 |
enddo |
2567 |
IF(tprof) then |
2568 |
do i=1,ISTNM1 |
2569 |
XLDIAG(I,1) = XLDIAG(I,1) + AITR*XL(I,1) |
2570 |
enddo |
2571 |
endif |
2572 |
FIRST = .FALSE. |
2573 |
C |
2574 |
C SAVE XL,CT,XX,YY,ZETA FOR USE BY MOIST BOUYANCY CALCULATION |
2575 |
C |
2576 |
IF(ITER.EQ.ITRTRB)THEN |
2577 |
DO I = 1,ISTNM1 |
2578 |
XLSAVE(I,1) = XL(I,1) |
2579 |
ENDDO |
2580 |
DO I = 1,irun |
2581 |
CTSAVE(I) = CT(I) |
2582 |
XXSAVE(I) = XX(I) |
2583 |
YYSAVE(I) = YY(I) |
2584 |
ZETASAVE(I) = ZETA(I) |
2585 |
ENDDO |
2586 |
ENDIF |
2587 |
|
2588 |
do i = 1,istnlv |
2589 |
turbfcc(i,1) = turbfcc(i,1) + fcc(i,1) * aitr |
2590 |
enddo |
2591 |
do i = 1,irun*nlev |
2592 |
qliq(i,1) = qliq(i,1) + shl(i,1) * aitr |
2593 |
enddo |
2594 |
C |
2595 |
C END OF MAIN LOOP |
2596 |
C |
2597 |
2000 CONTINUE |
2598 |
DO 9194 I =1,ISTNLV |
2599 |
WU(I,1) = WU(I,1) * AITR |
2600 |
WV(I,1) = WV(I,1) * AITR |
2601 |
9194 CONTINUE |
2602 |
C |
2603 |
RETURN |
2604 |
END |
2605 |
SUBROUTINE SFCFLX(NN,VUS,VVS,VTHV1,VTHV2,VTH1,VTH2,VSH1, |
2606 |
1 VSH2,VPK,VPKE,VPE,VZ0,IVWATER,VHS, |
2607 |
2 VAHS,FIRST,LAST,N,IRUN,aitr,VRHO,VRHOZPK,VKH,VKM, |
2608 |
3 VUSTAR,VXX,VYY,VCU,VCT,VRIB,VZETA,VWS, |
2609 |
4 stu2m,stv2m,stt2m,stq2m,stu10m,stv10m,stt10m,stq10m, |
2610 |
5 cp,rgas,undef, |
2611 |
6 lwater, ivbitrib, |
2612 |
7 VHZ,VPSIM,VAPSIM,VPSIG,VPSIHG,VTEMP,VDZETA,VDZ0,VDPSIM, |
2613 |
8 VDPSIH,VZH,VXX0,VYY0,VAPSIHG,VRIB1,VWS1,VPSIH,VZETAL, |
2614 |
9 VZ0L,VPSIH2,VH0, |
2615 |
3 VX0PSIM,VG,VG0,VR1MG0,VZ2,VDZSEA,VAZ0,VXNUM1,VPSIGB2,VDX, |
2616 |
4 VDXPSIM,VDY,VXNUM2,VDEN,VAWS1,VXNUM3,VXNUM,VDZETA1,VDZETA2, |
2617 |
5 VZCOEF2,VZCOEF1,VTEMPLIN,VDPSIMC,VDPSIHC) |
2618 |
C********************************************************************** |
2619 |
C SUBROUTINE SFCFLX - COMPUTES SURFACE TRANSFER COEFFICIENTS |
2620 |
C - CALLED FROM TRBFLX |
2621 |
C |
2622 |
C ARGUMENTS :: |
2623 |
C |
2624 |
C INPUT: |
2625 |
C ------ |
2626 |
C US - U - COMPONENT OF SURFACE WIND |
2627 |
C VS - V - COMPONENT OF SURFACE WIND |
2628 |
C THV1 - VIRTUAL POTENTIAL TEMPERATURE AT NLAY |
2629 |
C THV2 - VIRTUAL POTENTIAL TEMPERATURE AT GROUND |
2630 |
C TH1 - POTENTIAL TEMPERATURE AT NLAY |
2631 |
C TH2 - POTENTIAL TEMPERATURE AT GROUND |
2632 |
C SH1 - SPECIFIC HUMIDITY AT NLAY |
2633 |
C SH2 - SPECIFIC HUMIDITY AT GROUND |
2634 |
C PK - EVEN LEVEL PRESSURE ** KAPPA AT LEVEL NLAY |
2635 |
C PKE - EDGE LEVEL PRESSURE ** KAPPA AT GROUND |
2636 |
C PE - SURFACE PRESSURE |
2637 |
C Z0 - SURFACE ROUGHNESS |
2638 |
C WATER - BIT ARRAY - '1' OVER OCEANS |
2639 |
C HS - DEPTH OF SURFACE LAYER |
2640 |
C AHS - ONE / HS |
2641 |
C FIRST - LOGICAL .TRUE. FOR FIRST TRBFLX ITERATION |
2642 |
C LAST - LOGICAL .TRUE. FOR LAST TRBFLX ITERATION |
2643 |
C N - NUMBER OF SFCFLX ITERATIONS |
2644 |
C OUTPUT: |
2645 |
C ------- |
2646 |
C RHO - DENSITY AT 10M HEIGHT |
2647 |
C RHOZPK - RHO * P**K AT THE SURFACE |
2648 |
C KH - HEAT TRANSFER COEFFICIENT (CT*USTAR) |
2649 |
C KM - MOMENTUM TRANSFER COEFFICIENT (CU*USTAR) |
2650 |
C USTAR - FRICTION VELOCITY |
2651 |
C XX - PHIM(ZETA) - DIMENSIONLESS WIND SHEAR |
2652 |
C YY - PHIH(ZETA) - DIMENSIONLESS TEMP GRADIENT |
2653 |
C CU - MOMENTUM TRANSPORT COEFFICIENT |
2654 |
C CT - HEAT TRANSPORT COEFFICIENT |
2655 |
C |
2656 |
C********************************************************************** |
2657 |
implicit none |
2658 |
|
2659 |
C Argument List Declarations |
2660 |
integer nn,n,irun |
2661 |
_RL aitr,cp,rgas,undef |
2662 |
_RL VUS(IRUN),VVS(IRUN),VTHV1(IRUN),VTHV2(IRUN) |
2663 |
_RL VTH1(IRUN),VTH2(IRUN),VSH1(IRUN),VSH2(IRUN) |
2664 |
_RL VPK(IRUN),VPKE(IRUN),VPE(IRUN) |
2665 |
_RL VZ0(IRUN),VHS(IRUN),VAHS(IRUN) |
2666 |
integer IVWATER(IRUN) |
2667 |
LOGICAL FIRST,LAST |
2668 |
_RL VRHO(IRUN),VRHOZPK(IRUN) |
2669 |
_RL VKM(IRUN),VKH(IRUN),VUSTAR(IRUN),VXX(IRUN) |
2670 |
_RL VYY(IRUN),VCU(IRUN),VCT(IRUN),VRIB(IRUN) |
2671 |
_RL VZETA(IRUN),VWS(IRUN) |
2672 |
_RL stu2m(irun),stv2m(irun),stt2m(irun),stq2m(irun) |
2673 |
_RL stu10m(irun),stv10m(irun),stt10m(irun),stq10m(irun) |
2674 |
LOGICAL LWATER |
2675 |
integer IVBITRIB(irun) |
2676 |
_RL VHZ(irun),VPSIM(irun),VAPSIM(irun),VPSIG(irun),VPSIHG(irun) |
2677 |
_RL VTEMP(irun),VDZETA(irun),VDZ0(irun),VDPSIM(irun) |
2678 |
_RL VDPSIH(irun),VZH(irun),VXX0(irun),VYY0(irun) |
2679 |
_RL VAPSIHG(irun),VRIB1(irun),VWS1(irun) |
2680 |
_RL VPSIH(irun),VZETAL(irun),VZ0L(irun),VPSIH2(irun),VH0(irun) |
2681 |
_RL VX0PSIM(irun),VG(irun),VG0(irun),VR1MG0(irun) |
2682 |
_RL VZ2(irun),VDZSEA(irun),VAZ0(irun),VXNUM1(irun) |
2683 |
_RL VPSIGB2(irun),VDX(irun),VDXPSIM(irun),VDY(irun) |
2684 |
_RL VXNUM2(irun),VDEN(irun),VAWS1(irun),VXNUM3(irun) |
2685 |
_RL VXNUM(irun),VDZETA1(irun),VDZETA2(irun) |
2686 |
_RL VZCOEF2(irun),VZCOEF1(irun),VTEMPLIN(irun) |
2687 |
_RL VDPSIMC(irun),VDPSIHC(irun) |
2688 |
|
2689 |
C Local Variables |
2690 |
_RL USTMX3,USTZ0S,Z0MIN,H0BYZ0,USTH0S,H0VEG,Z0VEGM,PRFAC |
2691 |
_RL XPFAC,DIFSQT |
2692 |
PARAMETER ( USTMX3 = 0.0632456) |
2693 |
PARAMETER ( USTZ0S = 0.2030325E-5) |
2694 |
PARAMETER ( Z0MIN = USTZ0S/USTMX3) |
2695 |
PARAMETER ( H0BYZ0 = 30.0 ) |
2696 |
PARAMETER ( USTH0S = H0BYZ0*USTZ0S ) |
2697 |
PARAMETER ( H0VEG = 0.01 ) |
2698 |
PARAMETER ( Z0VEGM = 0.005 ) |
2699 |
PARAMETER ( PRFAC = 0.595864 ) |
2700 |
PARAMETER ( XPFAC = .55 ) |
2701 |
PARAMETER ( DIFSQT = 3.872983E-3) |
2702 |
|
2703 |
_RL psihdiag(irun),psimdiag(irun) |
2704 |
_RL getcon,vk,rvk,vk2,bmdl |
2705 |
integer iwater,itype |
2706 |
integer i,iter |
2707 |
C |
2708 |
vk = getcon('VON KARMAN') |
2709 |
rvk = 1./vk |
2710 |
vk2 = vk*vk |
2711 |
BMDL = VK * XPFAC * PRFAC / DIFSQT |
2712 |
|
2713 |
C DETERMINE SURFACE WIND MAGNITUDE AND BULK RICHARDSON NUMBER |
2714 |
C |
2715 |
DO 9000 I = 1,IRUN |
2716 |
VWS(I) = VUS(I) * VUS(I) + VVS(I) * VVS(I) |
2717 |
IF ( VWS(I) .LE. 1.e-4) VWS(I) = 1.e-4 |
2718 |
VRIB(I) = ( CP * (VPKE(I)-VPK(I)) ) * |
2719 |
1 (VTHV1(I) - VTHV2(I)) / VWS(I) |
2720 |
VWS(I) = SQRT( VWS(I) ) |
2721 |
9000 CONTINUE |
2722 |
C |
2723 |
C INITIALIZATION (FIRST TRBFLX ITERATION) |
2724 |
C INITIAL GUESS FOR ROUGHNESS LENGTH Z0 OVER WATER |
2725 |
C |
2726 |
IF (.NOT. FIRST) GO TO 100 |
2727 |
C |
2728 |
IWATER = 0 |
2729 |
DO 9002 I = 1,IRUN |
2730 |
IF (IVWATER(I).EQ.1) IWATER = IWATER + 1 |
2731 |
9002 CONTINUE |
2732 |
LWATER = .FALSE. |
2733 |
IF(IWATER.GE.1)LWATER = .TRUE. |
2734 |
C |
2735 |
IF(LWATER)THEN |
2736 |
DO 9004 I = 1,IRUN |
2737 |
IF (IVWATER(I).EQ.1) VZ0(I) = 0.0003 |
2738 |
9004 CONTINUE |
2739 |
ENDIF |
2740 |
do i = 1,irun |
2741 |
vh0(i) = h0byz0 * vz0(i) |
2742 |
if(vz0(i).ge.z0vegm)vh0(i) = h0veg |
2743 |
enddo |
2744 |
|
2745 |
C CU AND PSIHG FOR NEUTRALLY STRATIFIED FLOW |
2746 |
C |
2747 |
DO 9006 I = 1,IRUN |
2748 |
VHZ(I) = VHS(I) / VZ0(I) |
2749 |
VPSIM(I) = LOG( VHZ(I) ) |
2750 |
VAPSIM(I) = 1. / VPSIM(I) |
2751 |
VCU(I) = VK * VAPSIM(I) |
2752 |
VUSTAR(I) = VCU(I) * VWS(I) |
2753 |
C |
2754 |
VPSIG(I) = VH0(I) * VUSTAR(I) - USTH0S |
2755 |
if(VPSIG(I).lt.0.) VPSIG(I) = 0. |
2756 |
VPSIG(I) = SQRT( VPSIG(I) ) |
2757 |
VPSIG(I) = BMDL * VPSIG(I) |
2758 |
VPSIHG(I) = VPSIM(I) + VPSIG(I) |
2759 |
9006 CONTINUE |
2760 |
C |
2761 |
C LINEAR CORRECTION FOR ERROR IN ROUGHNESS LENGTH Z0 |
2762 |
C |
2763 |
IF(LWATER)THEN |
2764 |
DO 9008 I = 1,IRUN |
2765 |
VTEMP(I) = 0. |
2766 |
9008 CONTINUE |
2767 |
CALL LINADJ(NN,VRIB,VRIB,VWS, |
2768 |
1 VWS,VZ0,VUSTAR,IVWATER, |
2769 |
2 VAPSIM,VTEMP,VTEMP, |
2770 |
3 VTEMP,VTEMP,VTEMP, |
2771 |
4 VTEMP,VTEMP,1,.TRUE.,IRUN,VDZETA, |
2772 |
5 VDZ0,VDPSIM,VDPSIH, |
2773 |
6 IVBITRIB, |
2774 |
3 VX0PSIM,VG,VG0,VR1MG0,VZ2,VDZSEA,VAZ0,VXNUM1,VPSIGB2,VDX, |
2775 |
4 VDXPSIM,VDY,VXNUM2,VDEN,VAWS1,VXNUM3,VXNUM,VDZETA1,VDZETA2, |
2776 |
5 VZCOEF2,VZCOEF1,VTEMPLIN,VDPSIMC,VDPSIHC) |
2777 |
DO 9010 I = 1,IRUN |
2778 |
IF ( IVWATER(I).EQ.1 ) THEN |
2779 |
VCU(I) = VCU(I) * (1. - VDPSIM(I)*VAPSIM(I)) |
2780 |
VZ0(I) = VZ0(I) + VDZ0(I) |
2781 |
ENDIF |
2782 |
IF ( IVWATER(I).EQ.1) THEN |
2783 |
IF ( VZ0(I) .LE. Z0MIN ) VZ0(I) = Z0MIN |
2784 |
vh0(i) = h0byz0 * vz0(i) |
2785 |
VPSIG(I) = VH0(I) * VCU(I) * VWS(I) - USTH0S |
2786 |
if(VPSIG(I).lt.0.) VPSIG(I) = 0. |
2787 |
VPSIG(I) = SQRT( VPSIG(I) ) |
2788 |
VPSIG(I) = BMDL * VPSIG(I) |
2789 |
VPSIHG(I) = VPSIM(I) + VDPSIH(I) + VPSIG(I) |
2790 |
ENDIF |
2791 |
9010 CONTINUE |
2792 |
ENDIF |
2793 |
C |
2794 |
C INITIAL GUESS FOR STABILITY PARAMETER ZETA |
2795 |
C |
2796 |
DO 9012 I = 1,IRUN |
2797 |
VZETA(I) = VK2 * VRIB(I) / (VCU(I) * VCU(I) * VPSIHG(I)) |
2798 |
9012 CONTINUE |
2799 |
C |
2800 |
C RECOMPUTE CU, ESTIMATE PSIHG AND UPDATE ZETA AND Z0 |
2801 |
C |
2802 |
DO 9014 I = 1,IRUN |
2803 |
VZH(I) = VZ0(I) * VAHS(I) |
2804 |
9014 CONTINUE |
2805 |
CALL PSI (VZETA,VZH,VPSIM, |
2806 |
1 VTEMP,IRUN,VXX,VXX0,VYY, |
2807 |
2 VYY0,2) |
2808 |
DO 9016 I = 1,IRUN |
2809 |
VCU(I) = VK / VPSIM(I) |
2810 |
VPSIG(I) = VH0(I) * VCU(I) * VWS(I) - USTH0S |
2811 |
if(VPSIG(I).lt.0.) VPSIG(I) = 0. |
2812 |
VPSIG(I) = SQRT(VPSIG(I)) |
2813 |
VPSIG(I) = BMDL * VPSIG(I) |
2814 |
VPSIHG(I) = VPSIM(I) + VPSIG(I) |
2815 |
VZETA(I) = VK2 * VRIB(I) / (VCU(I) * VCU(I) * VPSIHG(I)) |
2816 |
9016 CONTINUE |
2817 |
C |
2818 |
IF(LWATER)THEN |
2819 |
CCCOOOMMMM ADDED 'WHERE WATER' |
2820 |
DO 9018 I = 1,IRUN |
2821 |
IF (IVWATER(I).EQ.1) VUSTAR(I) = VCU(I) * VWS(I) |
2822 |
9018 CONTINUE |
2823 |
CALL ZCSUB ( VUSTAR,VHZ,IVWATER,.FALSE.,IRUN,VTEMP) |
2824 |
DO 9020 I = 1,IRUN |
2825 |
IF (IVWATER(I).EQ.1 ) then |
2826 |
VZ0(I) = VTEMP(I) |
2827 |
IF ( VZ0(I) .LE. Z0MIN ) VZ0(I) = Z0MIN |
2828 |
vh0(i) = h0byz0 * vz0(i) |
2829 |
endif |
2830 |
9020 CONTINUE |
2831 |
ENDIF |
2832 |
C |
2833 |
GO TO 125 |
2834 |
C |
2835 |
C LINEARLY UPDATE ZETA AND Z0 FOR SECOND OR GREATER TRBFLX ITERATION |
2836 |
C |
2837 |
100 CONTINUE |
2838 |
|
2839 |
CALL LINADJ(NN,VRIB1,VRIB,VWS1, |
2840 |
1 VWS,VZ0,VUSTAR,IVWATER, |
2841 |
2 VAPSIM,VAPSIHG,VPSIH, |
2842 |
3 VPSIG,VXX,VXX0, |
2843 |
4 VYY,VYY0,2,LWATER,IRUN,VDZETA, |
2844 |
5 VDZ0,VDPSIM,VDPSIH, |
2845 |
6 IVBITRIB, |
2846 |
3 VX0PSIM,VG,VG0,VR1MG0,VZ2,VDZSEA,VAZ0,VXNUM1,VPSIGB2,VDX, |
2847 |
4 VDXPSIM,VDY,VXNUM2,VDEN,VAWS1,VXNUM3,VXNUM,VDZETA1,VDZETA2, |
2848 |
5 VZCOEF2,VZCOEF1,VTEMPLIN,VDPSIMC,VDPSIHC) |
2849 |
C |
2850 |
DO 9022 I = 1,IRUN |
2851 |
VZETA(I) = VZETA(I) + VZETAL(I) * VDZETA(I) |
2852 |
IF (IVBITRIB(I).EQ.1 )VZETA(I) = |
2853 |
1 VPSIM(I) * VPSIM(I) * VRIB(I) * VCT(I) * RVK |
2854 |
9022 CONTINUE |
2855 |
C |
2856 |
IF ( LWATER ) THEN |
2857 |
DO 9024 I = 1,IRUN |
2858 |
IF (IVWATER(I).EQ.1 ) then |
2859 |
VZ0(I) = VZ0(I) + VZ0L(I) * VDZ0(I) |
2860 |
IF (VZ0(I) .LE. Z0MIN ) VZ0(I) = Z0MIN |
2861 |
vh0(i) = h0byz0 * vz0(i) |
2862 |
endif |
2863 |
9024 CONTINUE |
2864 |
ENDIF |
2865 |
C |
2866 |
125 CONTINUE |
2867 |
C |
2868 |
C ITERATIVE LOOP - N ITERATIONS |
2869 |
C COMPUTE CU AND CT |
2870 |
C |
2871 |
DO 200 ITER = 1,N |
2872 |
DO 9026 I = 1,IRUN |
2873 |
VZH(I) = VZ0(I) * VAHS(I) |
2874 |
9026 CONTINUE |
2875 |
CALL PSI (VZETA,VZH,VPSIM, |
2876 |
1 VPSIH,IRUN,VXX,VXX0,VYY, |
2877 |
2 VYY0,1) |
2878 |
DO 9028 I = 1,IRUN |
2879 |
VCU(I) = VK / VPSIM(I) |
2880 |
VUSTAR(I) = VCU(I) * VWS(I) |
2881 |
C |
2882 |
VPSIG(I) = VH0(I) * VUSTAR(I) - USTH0S |
2883 |
if(VPSIG(I).lt.0.) VPSIG(I) = 0. |
2884 |
VPSIG(I) = SQRT(VPSIG(I)) |
2885 |
VPSIG(I) = BMDL * VPSIG(I) |
2886 |
VPSIHG(I) = VPSIH(I) + VPSIG(I) |
2887 |
C |
2888 |
C LINEAR CORRECTIONS FOR CU, CT, ZETA, AND Z0 |
2889 |
C |
2890 |
VAPSIM(I) = VCU(I) * RVK |
2891 |
VAPSIHG(I) = 1. / VPSIHG(I) |
2892 |
VRIB1(I) = VAPSIM(I) * VAPSIM(I) * VPSIHG(I) * VZETA(I) |
2893 |
9028 CONTINUE |
2894 |
C |
2895 |
ITYPE = 3 |
2896 |
IF(ITER.EQ.N) ITYPE = 4 |
2897 |
IF( (ITYPE.EQ.4) .AND. (.NOT.LAST) ) ITYPE = 5 |
2898 |
C |
2899 |
CALL LINADJ(NN,VRIB1,VRIB,VWS, |
2900 |
1 VWS,VZ0,VUSTAR,IVWATER, |
2901 |
2 VAPSIM,VAPSIHG,VPSIH, |
2902 |
3 VPSIG,VXX,VXX0, |
2903 |
4 VYY,VYY0,ITYPE,LWATER,IRUN,VDZETA, |
2904 |
5 VDZ0,VDPSIM,VDPSIH, |
2905 |
6 IVBITRIB, |
2906 |
3 VX0PSIM,VG,VG0,VR1MG0,VZ2,VDZSEA,VAZ0,VXNUM1,VPSIGB2,VDX, |
2907 |
4 VDXPSIM,VDY,VXNUM2,VDEN,VAWS1,VXNUM3,VXNUM,VDZETA1,VDZETA2, |
2908 |
5 VZCOEF2,VZCOEF1,VTEMPLIN,VDPSIMC,VDPSIHC) |
2909 |
C |
2910 |
C UPDATES OF ZETA, Z0, CU AND CT |
2911 |
C |
2912 |
IF (ITYPE.EQ.5) THEN |
2913 |
DO 9030 I = 1,IRUN |
2914 |
VZETAL(I) = VZETA(I) |
2915 |
VZ0L(I) = VZ0(I) |
2916 |
9030 CONTINUE |
2917 |
ENDIF |
2918 |
C |
2919 |
DO 9032 I = 1,IRUN |
2920 |
VZETA(I) = VZETA(I) * ( 1. + VDZETA(I) ) |
2921 |
IF (IVBITRIB(I).EQ.1 ) VZETA(I) = |
2922 |
1 VPSIM(I) * VPSIM(I) * VRIB(I) * VAPSIHG(I) |
2923 |
9032 CONTINUE |
2924 |
C |
2925 |
IF ( LWATER ) THEN |
2926 |
DO 9034 I = 1,IRUN |
2927 |
IF (IVWATER(I).EQ.1 ) then |
2928 |
VZ0(I) = VZ0(I) * ( 1. + VDZ0(I) ) |
2929 |
IF (VZ0(I) .LE. Z0MIN ) VZ0(I) = Z0MIN |
2930 |
vh0(i) = h0byz0 * vz0(i) |
2931 |
endif |
2932 |
9034 CONTINUE |
2933 |
ENDIF |
2934 |
C |
2935 |
IF ( ITER .EQ. N ) THEN |
2936 |
DO 9036 I = 1,IRUN |
2937 |
VPSIM(I) = VPSIM(I) + VDPSIM(I) |
2938 |
VCU(I) = VK / VPSIM(I) |
2939 |
VUSTAR(I) = VCU(I) * VWS(I) |
2940 |
C |
2941 |
VPSIG(I) = VH0(I) * VUSTAR(I) - USTH0S |
2942 |
if(VPSIG(I).lt.0.) VPSIG(I) = 0. |
2943 |
VPSIG(I) = SQRT(VPSIG(I)) |
2944 |
VPSIG(I) = BMDL * VPSIG(I) |
2945 |
VPSIHG(I) = VPSIH(I) + VDPSIH(I) + VPSIG(I) |
2946 |
VCT(I) = VK / VPSIHG(I) |
2947 |
9036 CONTINUE |
2948 |
ENDIF |
2949 |
C |
2950 |
C SAVE VALUES OF RIB AND WS FOR NEXT ITERATION OF TRBFLX |
2951 |
C |
2952 |
IF (ITYPE.EQ.5) THEN |
2953 |
DO 9038 I = 1,IRUN |
2954 |
VRIB1(I) = VRIB(I) |
2955 |
VWS1(I) = VWS(I) |
2956 |
9038 CONTINUE |
2957 |
ENDIF |
2958 |
C |
2959 |
200 CONTINUE |
2960 |
C |
2961 |
C CALCULATE RHO-SURFACE ( KG / M**3 ) |
2962 |
C |
2963 |
IF (FIRST) THEN |
2964 |
DO I = 1,IRUN |
2965 |
VTEMP(I) = 10. * VAHS(I) * VZETA(I) |
2966 |
VZH(I) = VZ0(I) * 0.1 |
2967 |
ENDDO |
2968 |
CALL PSI (VTEMP,VZH,VHZ, |
2969 |
1 VPSIH2,IRUN,VHZ,VHZ,VHZ, |
2970 |
2 VHZ,3) |
2971 |
DO I = 1,IRUN |
2972 |
VTEMP(I) = ( VPSIH2(I) + VPSIG(I) ) / VPSIHG(I) |
2973 |
VRHO(I) = VPKE(I)*( VTH2(I) + VTEMP(I) * (VTH1(I)-VTH2(I)) ) |
2974 |
VRHO(I) = VPE(I)*100. / ( RGAS * VRHO(I) ) |
2975 |
ENDDO |
2976 |
ENDIF |
2977 |
C |
2978 |
C interpolate uvtq to 2m and to 10 meters for diagnostic output |
2979 |
C use psih and psim which represent non-dim change from ground |
2980 |
C to specified level |
2981 |
C and multiply theta by surface p**kappa to get temperatures |
2982 |
C |
2983 |
do i = 1,irun |
2984 |
vtemp(i) = 2. * vahs(i) * vzeta(i) |
2985 |
vzh(i) = vz0(i) * 0.5 |
2986 |
if(vz0(i).ge.2.)vzh(i) = 0.9 |
2987 |
enddo |
2988 |
call psi(vtemp,vzh,psimdiag,psihdiag,irun,vhz,vhz,vhz,vhz,1) |
2989 |
do i = 1,irun |
2990 |
stu2m(i) = (psimdiag(i)/vpsim(i) * vus(i)) |
2991 |
stv2m(i) = (psimdiag(i)/vpsim(i) * vvs(i)) |
2992 |
stt2m(i) = ( (vth2(i) + ((psihdiag(i)+vpsig(i))/vpsihg(i))* |
2993 |
1 (vth1(i)-vth2(i))) ) * vpke(i) |
2994 |
stq2m(i) = (vsh2(i) + ((psihdiag(i)+vpsig(i))/vpsihg(i))* |
2995 |
1 (vsh1(i)-vsh2(i))) |
2996 |
if(vz0(i).ge.2.)then |
2997 |
stu2m(i) = UNDEF |
2998 |
stv2m(i) = UNDEF |
2999 |
stt2m(i) = UNDEF |
3000 |
stq2m(i) = UNDEF |
3001 |
endif |
3002 |
enddo |
3003 |
do i = 1,irun |
3004 |
vtemp(i) = 10. * vahs(i) * vzeta(i) |
3005 |
vzh(i) = vz0(i) * 0.1 |
3006 |
enddo |
3007 |
call psi(vtemp,vzh,psimdiag,psihdiag,irun,vhz,vhz,vhz,vhz,1) |
3008 |
do i = 1,irun |
3009 |
stu10m(i) = (psimdiag(i)/vpsim(i) * vus(i)) |
3010 |
stv10m(i) = (psimdiag(i)/vpsim(i) * vvs(i)) |
3011 |
stt10m(i) = ( (vth2(i) + ((psihdiag(i)+vpsig(i))/vpsihg(i))* |
3012 |
1 (vth1(i)-vth2(i))) ) * vpke(i) |
3013 |
stq10m(i) = (vsh2(i) + ((psihdiag(i)+vpsig(i))/vpsihg(i))* |
3014 |
1 (vsh1(i)-vsh2(i))) |
3015 |
enddo |
3016 |
C |
3017 |
C EVALUATE TURBULENT TRANSFER COEFFICIENTS |
3018 |
C |
3019 |
DO 9044 I = 1,IRUN |
3020 |
VRHOZPK(I) = VRHO(I) * VPKE(I) |
3021 |
VKH(I) = VUSTAR(I) * VCT(I) |
3022 |
VKM(I) = VUSTAR(I) * VCU(I) |
3023 |
9044 CONTINUE |
3024 |
C |
3025 |
RETURN |
3026 |
END |
3027 |
SUBROUTINE PHI(Z,PHIM,PHIH,IFLAG,N) |
3028 |
C********************************************************************** |
3029 |
C |
3030 |
C FUNCTION PHI - SOLVES KEYPS EQUATIONS |
3031 |
C - CALLED FROM PSI |
3032 |
C |
3033 |
C DESCRIPTION OF PARAMETERS |
3034 |
C Z - INPUTED VALUE OF MONIN- OBUKHOV STABILITY PARAMETER ZETA |
3035 |
C TIMES APPROPRIATE CONSTANT |
3036 |
C PHIM - OUTPUTED SOLUTION OF KEYPS EQUATION FOR MOMENTUM |
3037 |
C PHIH - OUTPUTED SOLUTION OF KEYPS EQUATION FOR SCALARS |
3038 |
C IFLAG - FLAG TO DETERMINE IF X IS NEEDED (IFLAG=2), Y IS NEEDED |
3039 |
C (IFLAG=3), OR BOTH (IFLAG=1) |
3040 |
C N - LENGTH OF VECTOR TO BE SOLVED |
3041 |
C |
3042 |
C********************************************************************** |
3043 |
implicit none |
3044 |
|
3045 |
C Argument List Declarations |
3046 |
integer n,iflag |
3047 |
_RL PHIM(N),PHIH(N),Z(N) |
3048 |
|
3049 |
C Local Variables |
3050 |
integer I1(N),I2(N) |
3051 |
_RL ZSTAR(N),E1(N),E2(N),TEMP1(N) |
3052 |
C |
3053 |
_RL PHIM0(385),ZLINM1(75),ZLINM2(75),ZLINM3(36) |
3054 |
_RL ZLOGM1(74),ZLOGM2(75),ZLOGM3(50) |
3055 |
_RL PHIH0(385),ZLINH1(75),ZLINH2(75),ZLINH3(36) |
3056 |
_RL ZLOGH1(74),ZLOGH2(75),ZLOGH3(50) |
3057 |
EQUIVALENCE (PHIM0(1),ZLINM1(1)),(PHIM0(76),ZLINM2(1)) |
3058 |
EQUIVALENCE (PHIM0(151),ZLINM3(1)) |
3059 |
EQUIVALENCE (PHIM0(187),ZLOGM1(1)),(PHIM0(261),ZLOGM2(1)) |
3060 |
EQUIVALENCE (PHIM0(336),ZLOGM3(1)) |
3061 |
EQUIVALENCE (PHIH0(1),ZLINH1(1)),(PHIH0(76),ZLINH2(1)) |
3062 |
EQUIVALENCE (PHIH0(151),ZLINH3(1)) |
3063 |
EQUIVALENCE (PHIH0(187),ZLOGH1(1)),(PHIH0(261),ZLOGH2(1)) |
3064 |
EQUIVALENCE (PHIH0(336),ZLOGH3(1)) |
3065 |
C |
3066 |
DATA ZLOGM1/ |
3067 |
. 0.697894,0.678839,0.659598,0.640260, |
3068 |
. 0.620910,0.601628,0.582486,0.563550,0.544877, |
3069 |
. 0.526519,0.508516,0.490903,0.473708,0.456951, |
3070 |
. 0.440649,0.424812,0.409446,0.394553,0.380133, |
3071 |
. 0.366182,0.352695,0.339664,0.327082,0.314938, |
3072 |
. 0.303222,0.291923,0.281029,0.270528,0.260409, |
3073 |
. 0.250659,0.241267,0.232221,0.223509,0.215119, |
3074 |
. 0.207041,0.199264,0.191776,0.184568,0.177628, |
3075 |
. 0.170949,0.164519,0.158331,0.152374,0.146641, |
3076 |
. 0.141123,0.135813,0.130702,0.125783,0.121048, |
3077 |
. 0.116492,0.112107,0.107887,0.103826,0.0999177, |
3078 |
. 0.0961563,0.0925364,0.0890528,0.0857003,0.0824739, |
3079 |
. 0.0793690,0.0763810,0.0735054,0.0707380,0.0680749, |
3080 |
. 0.0655120,0.0630455,0.0606720,0.0583877,0.0561895, |
3081 |
. 0.0540740,0.0520382,0.0500790,0.0481936,0.0463791/ |
3082 |
DATA ZLOGM2/ |
3083 |
. 0.0446330,0.0429526,0.0413355,0.0397792,0.0382816, |
3084 |
. 0.0368403,0.0354533,0.0341185,0.0328340,0.0315978, |
3085 |
. 0.0304081,0.0292633,0.0281616,0.0271013,0.0260809, |
3086 |
. 0.0250990,0.0241540,0.0232447,0.0223695,0.0215273, |
3087 |
. 0.0207168,0.0199369,0.0191862,0.0184639,0.0177687, |
3088 |
. 0.0170998,0.0164560,0.0158364,0.0152402,0.0146664, |
3089 |
. 0.0141142,0.0135828,0.0130714,0.0125793,0.0121057, |
3090 |
. 0.0116499,0.0112113,0.0107892,0.0103830,0.999210E-2, |
3091 |
. 0.961590E-2,0.925387E-2,0.890547E-2,0.857018E-2,0.824752E-2, |
3092 |
. 0.793701E-2,0.763818E-2,0.735061E-2,0.707386E-2,0.680754E-2, |
3093 |
. 0.655124E-2,0.630459E-2,0.606722E-2,0.583880E-2,0.561897E-2, |
3094 |
. 0.540742E-2,0.520383E-2,0.500791E-2,0.481937E-2,0.463792E-2, |
3095 |
. 0.446331E-2,0.429527E-2,0.413355E-2,0.397793E-2,0.382816E-2, |
3096 |
. 0.368403E-2,0.354533E-2,0.341185E-2,0.328340E-2,0.315978E-2, |
3097 |
. 0.304082E-2,0.292633E-2,0.281616E-2,0.271013E-2,0.260809E-2/ |
3098 |
DATA ZLOGM3/ |
3099 |
. 0.250990E-2,0.241541E-2,0.232447E-2,0.223695E-2,0.215273E-2, |
3100 |
. 0.207168E-2,0.199369E-2,0.191862E-2,0.184639E-2,0.177687E-2, |
3101 |
. 0.170998E-2,0.164560E-2,0.158364E-2,0.152402E-2,0.146664E-2, |
3102 |
. 0.141142E-2,0.135828E-2,0.130714E-2,0.125793E-2,0.121057E-2, |
3103 |
. 0.116499E-2,0.112113E-2,0.107892E-2,0.103830E-2,0.999210E-3, |
3104 |
. 0.961590E-3,0.925387E-3,0.890547E-3,0.857018E-3,0.824752E-3, |
3105 |
. 0.793701E-3,0.763818E-3,0.735061E-3,0.707386E-3,0.680754E-3, |
3106 |
. 0.655124E-3,0.630459E-3,0.606722E-3,0.583880E-3,0.561897E-3, |
3107 |
. 0.540742E-3,0.520383E-3,0.500791E-3,0.481937E-3,0.463792E-3, |
3108 |
. 0.446331E-3,0.429527E-3,0.413355E-3,0.397793E-3,0.382816E-3/ |
3109 |
DATA ZLOGH1/ |
3110 |
. 0.640529,0.623728,0.606937,0.590199, |
3111 |
. 0.573552,0.557032,0.540672,0.524504,0.508553, |
3112 |
. 0.492843,0.477397,0.462232,0.447365,0.432809, |
3113 |
. 0.418574,0.404670,0.391103,0.377878,0.364999, |
3114 |
. 0.352468,0.340284,0.328447,0.316954,0.305804, |
3115 |
. 0.294992,0.284514,0.274364,0.264538,0.255028, |
3116 |
. 0.245829,0.236933,0.228335,0.220026,0.211999, |
3117 |
. 0.204247,0.196762,0.189537,0.182564,0.175837, |
3118 |
. 0.169347,0.163088,0.157051,0.151231,0.145620, |
3119 |
. 0.140211,0.134998,0.129974,0.125133,0.120469, |
3120 |
. 0.115975,0.111645,0.107475,0.103458,0.995895E-1, |
3121 |
. 0.958635E-1,0.922753E-1,0.888199E-1,0.854925E-1,0.822886E-1, |
3122 |
. 0.792037E-1,0.762336E-1,0.733739E-1,0.706208E-1,0.679704E-1, |
3123 |
. 0.654188E-1,0.629625E-1,0.605979E-1,0.583217E-1,0.561306E-1, |
3124 |
. 0.540215E-1,0.519914E-1,0.500373E-1,0.481564E-1,0.463460E-1/ |
3125 |
DATA ZLOGH2/ |
3126 |
. 0.446034E-1,0.429263E-1,0.413120E-1,0.397583E-1,0.382629E-1, |
3127 |
. 0.368237E-1,0.354385E-1,0.341053E-1,0.328222E-1,0.315873E-1, |
3128 |
. 0.303988E-1,0.292550E-1,0.281541E-1,0.270947E-1,0.260750E-1, |
3129 |
. 0.250937E-1,0.241494E-1,0.232405E-1,0.223658E-1,0.215240E-1, |
3130 |
. 0.207139E-1,0.199342E-1,0.191839E-1,0.184618E-1,0.177669E-1, |
3131 |
. 0.170981E-1,0.164545E-1,0.158351E-1,0.152390E-1,0.146653E-1, |
3132 |
. 0.141133E-1,0.135820E-1,0.130707E-1,0.125786E-1,0.121051E-1, |
3133 |
. 0.116494E-1,0.112108E-1,0.107888E-1,0.103826E-1,0.999177E-2, |
3134 |
. 0.961561E-2,0.925360E-2,0.890523E-2,0.856997E-2,0.824733E-2, |
3135 |
. 0.793684E-2,0.763803E-2,0.735048E-2,0.707375E-2,0.680743E-2, |
3136 |
. 0.655114E-2,0.630450E-2,0.606715E-2,0.583873E-2,0.561891E-2, |
3137 |
. 0.540737E-2,0.520379E-2,0.500787E-2,0.481933E-2,0.463789E-2, |
3138 |
. 0.446328E-2,0.429524E-2,0.413353E-2,0.397790E-2,0.382814E-2, |
3139 |
. 0.368401E-2,0.354532E-2,0.341184E-2,0.328338E-2,0.315977E-2, |
3140 |
. 0.304081E-2,0.292632E-2,0.281615E-2,0.271012E-2,0.260809E-2/ |
3141 |
DATA ZLOGH3/ |
3142 |
. 0.250990E-2,0.241540E-2,0.232446E-2,0.223695E-2,0.215273E-2, |
3143 |
. 0.207168E-2,0.199368E-2,0.191862E-2,0.184639E-2,0.177687E-2, |
3144 |
. 0.170997E-2,0.164559E-2,0.158364E-2,0.152402E-2,0.146664E-2, |
3145 |
. 0.141142E-2,0.135828E-2,0.130714E-2,0.125793E-2,0.121057E-2, |
3146 |
. 0.116499E-2,0.112113E-2,0.107892E-2,0.103830E-2,0.999209E-3, |
3147 |
. 0.961590E-3,0.925387E-3,0.890546E-3,0.857018E-3,0.824752E-3, |
3148 |
. 0.793700E-3,0.763818E-3,0.735061E-3,0.707386E-3,0.680754E-3, |
3149 |
. 0.655124E-3,0.630459E-3,0.606722E-3,0.583880E-3,0.561897E-3, |
3150 |
. 0.540742E-3,0.520383E-3,0.500791E-3,0.481937E-3,0.463792E-3, |
3151 |
. 0.446331E-3,0.429527E-3,0.413355E-3,0.397793E-3,0.382816E-3/ |
3152 |
C |
3153 |
DATA ZLINM1/ |
3154 |
& 0.964508,0.962277,0.960062,0.957863,0.955680, |
3155 |
& 0.953512,0.951359,0.949222,0.947100,0.944992, |
3156 |
& 0.942899,0.940821,0.938758,0.936709,0.934673, |
3157 |
& 0.932652,0.930645,0.928652,0.926672,0.924706, |
3158 |
& 0.922753,0.920813,0.918886,0.916973,0.915072, |
3159 |
& 0.913184,0.911308,0.909445,0.907594,0.905756, |
3160 |
& 0.903930,0.902115,0.900313,0.898522,0.896743, |
3161 |
& 0.894975,0.893219,0.891475,0.889741,0.888019, |
3162 |
& 0.886307,0.884607,0.882917,0.881238,0.879569, |
3163 |
& 0.877911,0.876264,0.874626,0.872999,0.871382, |
3164 |
& 0.869775,0.868178,0.866591,0.865013,0.863445, |
3165 |
& 0.861887,0.860338,0.858798,0.857268,0.855747, |
3166 |
& 0.854235,0.852732,0.851238,0.849753,0.848277, |
3167 |
& 0.846809,0.845350,0.843900,0.842458,0.841025, |
3168 |
& 0.839599,0.838182,0.836774,0.835373,0.833980/ |
3169 |
DATA ZLINM2/ |
3170 |
& 0.832596,0.831219,0.829850,0.828489,0.827136, |
3171 |
& 0.825790,0.824451,0.823121,0.821797,0.820481, |
3172 |
& 0.819173,0.817871,0.816577,0.815289,0.814009, |
3173 |
& 0.812736,0.811470,0.810210,0.808958,0.807712, |
3174 |
& 0.806473,0.805240,0.804015,0.802795,0.801582, |
3175 |
& 0.800376,0.799176,0.797982,0.796794,0.795613, |
3176 |
& 0.794438,0.793269,0.792106,0.790949,0.789798, |
3177 |
& 0.788652,0.787513,0.786380,0.785252,0.784130, |
3178 |
& 0.783014,0.781903,0.780798,0.779698,0.778604, |
3179 |
& 0.777516,0.776432,0.775354,0.774282,0.773215, |
3180 |
& 0.772153,0.771096,0.770044,0.768998,0.767956, |
3181 |
& 0.766920,0.765888,0.764862,0.763840,0.762824, |
3182 |
& 0.761812,0.760805,0.759803,0.758805,0.757813, |
3183 |
& 0.756824,0.755841,0.754862,0.753888,0.752918, |
3184 |
& 0.751953,0.750992,0.750035,0.749083,0.748136/ |
3185 |
DATA ZLINM3/ |
3186 |
& 0.747192,0.746253,0.745318,0.744388,0.743462, |
3187 |
& 0.742539,0.741621,0.740707,0.739798,0.738892, |
3188 |
& 0.737990,0.737092,0.736198,0.735308,0.734423, |
3189 |
& 0.733540,0.732662,0.731788,0.730917,0.730050, |
3190 |
& 0.729187,0.728328,0.727472,0.726620,0.725772, |
3191 |
& 0.724927,0.724086,0.723248,0.722414,0.721584, |
3192 |
& 0.720757,0.719933,0.719113,0.718296,0.717483, |
3193 |
& 0.716673/ |
3194 |
DATA ZLINH1/ |
3195 |
& 0.936397,0.932809,0.929287,0.925827,0.922429, |
3196 |
& 0.919089,0.915806,0.912579,0.909405,0.906284, |
3197 |
& 0.903212,0.900189,0.897214,0.894284,0.891399, |
3198 |
& 0.888558,0.885759,0.883001,0.880283,0.877603, |
3199 |
& 0.874962,0.872357,0.869788,0.867255,0.864755, |
3200 |
& 0.862288,0.859854,0.857452,0.855081,0.852739, |
3201 |
& 0.850427,0.848144,0.845889,0.843662,0.841461, |
3202 |
& 0.839287,0.837138,0.835014,0.832915,0.830841, |
3203 |
& 0.828789,0.826761,0.824755,0.822772,0.820810, |
3204 |
& 0.818869,0.816949,0.815050,0.813170,0.811310, |
3205 |
& 0.809470,0.807648,0.805845,0.804060,0.802293, |
3206 |
& 0.800543,0.798811,0.797095,0.795396,0.793714, |
3207 |
& 0.792047,0.790396,0.788761,0.787141,0.785535, |
3208 |
& 0.783945,0.782369,0.780807,0.779259,0.777724, |
3209 |
& 0.776204,0.774696,0.773202,0.771720,0.770251/ |
3210 |
DATA ZLINH2/ |
3211 |
& 0.768795,0.767351,0.765919,0.764499,0.763091, |
3212 |
& 0.761694,0.760309,0.758935,0.757571,0.756219, |
3213 |
& 0.754878,0.753547,0.752226,0.750916,0.749616, |
3214 |
& 0.748326,0.747045,0.745775,0.744514,0.743262, |
3215 |
& 0.742020,0.740787,0.739563,0.738348,0.737141, |
3216 |
& 0.735944,0.734755,0.733574,0.732402,0.731238, |
3217 |
& 0.730083,0.728935,0.727795,0.726664,0.725539, |
3218 |
& 0.724423,0.723314,0.722213,0.721119,0.720032, |
3219 |
& 0.718952,0.717880,0.716815,0.715756,0.714704, |
3220 |
& 0.713660,0.712621,0.711590,0.710565,0.709547, |
3221 |
& 0.708534,0.707529,0.706529,0.705536,0.704549, |
3222 |
& 0.703567,0.702592,0.701623,0.700660,0.699702, |
3223 |
& 0.698750,0.697804,0.696863,0.695928,0.694998, |
3224 |
& 0.694074,0.693155,0.692241,0.691333,0.690430, |
3225 |
& 0.689532,0.688639,0.687751,0.686868,0.685990/ |
3226 |
DATA ZLINH3/ |
3227 |
& 0.685117,0.684249,0.683386,0.682527,0.681673, |
3228 |
& 0.680824,0.679979,0.679139,0.678303,0.677472, |
3229 |
& 0.676645,0.675823,0.675005,0.674191,0.673381, |
3230 |
& 0.672576,0.671775,0.670978,0.670185,0.669396, |
3231 |
& 0.668611,0.667830,0.667054,0.666281,0.665512, |
3232 |
& 0.664746,0.663985,0.663227,0.662473,0.661723, |
3233 |
& 0.660977,0.660234,0.659495,0.658759,0.658027, |
3234 |
& 0.657298/ |
3235 |
|
3236 |
integer ibit1,ibit2,i |
3237 |
C |
3238 |
IBIT1 = 0 |
3239 |
IBIT2 = 0 |
3240 |
C |
3241 |
DO 9000 I = 1,N |
3242 |
IF(Z(I).GE.0.15)IBIT1 = IBIT1 + 1 |
3243 |
IF(Z(I).GT.2. )IBIT2 = IBIT2 + 1 |
3244 |
9000 CONTINUE |
3245 |
C |
3246 |
IF( IBIT1 .LE. 0 ) GO TO 200 |
3247 |
C |
3248 |
DO 9002 I = 1,N |
3249 |
ZSTAR(I) = 100. * Z(I) - 14. |
3250 |
9002 CONTINUE |
3251 |
C |
3252 |
IF( IBIT2 .LE. 0 ) GO TO 60 |
3253 |
DO 9004 I = 1,N |
3254 |
TEMP1(I) = Z(I)*0.5 |
3255 |
IF( Z(I) .LE. 2. )TEMP1(I) = 1. |
3256 |
TEMP1(I) = LOG10(TEMP1(I)) |
3257 |
TEMP1(I) = (TEMP1(I) + 9.3) * 20. |
3258 |
IF( Z(I) .GT. 2. ) ZSTAR(I) = TEMP1(I) |
3259 |
IF( Z(I).GT.1.78e10 ) ZSTAR(I) = 384.9999 |
3260 |
9004 CONTINUE |
3261 |
C |
3262 |
60 CONTINUE |
3263 |
C |
3264 |
DO 9006 I = 1,N |
3265 |
I1(I) = ZSTAR(I) |
3266 |
I2(I) = I1(I) + 1 |
3267 |
TEMP1(I) = ZSTAR(I) - I1(I) |
3268 |
C |
3269 |
9006 CONTINUE |
3270 |
C |
3271 |
IF( IFLAG .GT. 2 ) GO TO 100 |
3272 |
DO 9008 I = 1,N |
3273 |
if( z(i).ge.0.15 ) then |
3274 |
E1(I) = PHIM0( I1(I) ) |
3275 |
E2(I) = PHIM0( I2(I) ) |
3276 |
PHIM(I) = TEMP1(I) * ( E2(I)-E1(I) ) |
3277 |
PHIM(I) = PHIM(I) + E1(I) |
3278 |
endif |
3279 |
9008 CONTINUE |
3280 |
|
3281 |
100 CONTINUE |
3282 |
C |
3283 |
IF( IFLAG .EQ. 2 ) GO TO 200 |
3284 |
DO 9010 I = 1,N |
3285 |
if( z(i).ge.0.15 ) then |
3286 |
E1(I) = PHIH0( I1(I) ) |
3287 |
E2(I) = PHIH0( I2(I) ) |
3288 |
PHIH(I) = TEMP1(I) * ( E2(I)-E1(I) ) |
3289 |
PHIH(I) = PHIH(I) + E1(I) |
3290 |
endif |
3291 |
9010 CONTINUE |
3292 |
|
3293 |
200 CONTINUE |
3294 |
IF( IBIT1 .GE. N ) GO TO 500 |
3295 |
C |
3296 |
DO 9012 I = 1,N |
3297 |
ZSTAR(I) = -Z(I) |
3298 |
9012 CONTINUE |
3299 |
C |
3300 |
IF( IFLAG .GT. 2 ) GO TO 300 |
3301 |
DO 9014 I = 1,N |
3302 |
IF( Z(I) .LT. 0.15 ) PHIM(I) = 1. + ZSTAR(I) |
3303 |
2 *(0.25+ZSTAR(I)*(0.09375+ZSTAR(I)* |
3304 |
3 (0.03125+0.00732422 * ZSTAR(I)))) |
3305 |
9014 CONTINUE |
3306 |
C |
3307 |
300 CONTINUE |
3308 |
IF( IFLAG .EQ. 2 ) GO TO 500 |
3309 |
DO 9016 I = 1,N |
3310 |
IF( Z(I) .LT. 0.15 ) THEN |
3311 |
PHIH(I) =1.+ Z(I) * (0.5+ZSTAR(I)*(0.375+ZSTAR(I)* |
3312 |
1 (0.5+ZSTAR(I)*(0.8203125+ZSTAR(I)* |
3313 |
2 (1.5+2.93262*ZSTAR(I)))))) |
3314 |
PHIH(I) = 1. / PHIH(I) |
3315 |
ENDIF |
3316 |
9016 CONTINUE |
3317 |
C |
3318 |
500 CONTINUE |
3319 |
RETURN |
3320 |
END |
3321 |
SUBROUTINE PSI(VZZ,VZH,VPSIM,VPSIH,IRUN,VX,VXS,VY,VYS,IFLAG) |
3322 |
C********************************************************************** |
3323 |
C |
3324 |
C SUBROUTINE PSI - DETERMINES DIMENSIONLESS WIND AND |
3325 |
C SCALAR PROFILES IN SURFACE LAYER |
3326 |
C - CALLED FROM SFCFLX |
3327 |
C |
3328 |
C DESCRIPTION OF PARAMETERS |
3329 |
C ZZ - INPUTED VALUE OF MONIN- OBUKHOV STABILITY PARAMETER ZETA |
3330 |
C ZH - INPUTED VALUE OF PBL HEIGHT DIVIDED BY Z0 |
3331 |
C PSIM - OUTPUTED VALUE OF DIMENSIONLESS WIND |
3332 |
C PSIH - OUTPUTED VALUE OF DIMENSIONLESS SCALAR |
3333 |
C X - OUTPUTED VALUE OF PHIM(ZETA) |
3334 |
C XS - OUTPUTED VALUE OF PHIM(ZETA0) |
3335 |
C Y - OUTPUTED VALUE OF PHIH(ZETA) |
3336 |
C YS - OUTPUTED VALUE OF PHIH(ZETA0) |
3337 |
C IFLAG- FLAG TO DETERMINE IF CU IS NEEDED (IFLAG=2), |
3338 |
C IF CT IS NEEDED (IFLAG=3), OR BOTH (IFLAG=1) |
3339 |
C SUBPROGRAMS NEEDED |
3340 |
C PHI - COMPUTES SIMILARITY FUNCTION FOR MOMENTUM AND SCALARS |
3341 |
C |
3342 |
C********************************************************************** |
3343 |
implicit none |
3344 |
|
3345 |
C Argument List Declarations |
3346 |
integer irun,iflag |
3347 |
_RL VZZ(IRUN),VZH(IRUN),VPSIM(IRUN),VPSIH(IRUN), |
3348 |
1 VX(IRUN),VXS(IRUN),VY(IRUN),VYS(IRUN) |
3349 |
|
3350 |
C Local Variables |
3351 |
_RL ZWM,RZWM,Z0M,ZCM,RZCM,CM1,CM2,CM6,CM7,CM8ARG,YCM |
3352 |
PARAMETER ( ZWM = 1. ) |
3353 |
PARAMETER ( RZWM = 1./ZWM ) |
3354 |
PARAMETER ( Z0M = 0.2 ) |
3355 |
PARAMETER ( ZCM = 42. ) |
3356 |
PARAMETER ( RZCM = 1./ZCM ) |
3357 |
PARAMETER ( CM1 = 1./126. ) |
3358 |
PARAMETER ( CM2 = 1./(6.*CM1) ) |
3359 |
PARAMETER ( CM6 = 6. / ( 1. + 6.*CM1 ) ) |
3360 |
PARAMETER ( CM7 = CM2 + ZWM ) |
3361 |
PARAMETER ( CM8ARG = CM7*ZCM*RZWM / (CM2+ZCM) ) |
3362 |
PARAMETER ( YCM = 6. / ( 1. + 6.*CM1*ZCM ) ) |
3363 |
|
3364 |
integer INTSTB(irun),INTZ0(irun) |
3365 |
_RL ZZ0(irun),Z(irun),Z2(irun),Z1(irun),Z0(irun) |
3366 |
_RL X0(irun),X1(irun),Y0(irun),Y1(irun) |
3367 |
_RL PSI2(irun),TEMP(irun) |
3368 |
_RL HZ(irun),ARG0(irun),ARG1(irun),DX(irun) |
3369 |
_RL X0NUM(irun),X1NUM(irun),X0DEN(irun) |
3370 |
_RL X1DEN(irun),Y1DEN(irun),Z2ZWM(irun) |
3371 |
_RL cm3,cm4,cm5,cm8 |
3372 |
integer ibit,indx |
3373 |
integer i |
3374 |
C |
3375 |
CM3 = sqrt( 0.2/CM1-0.01 ) |
3376 |
CM4 = 1./CM3 |
3377 |
CM5 = (10.-CM1) / (10.*CM1*CM3) |
3378 |
CM8 = 6. * LOG(CM8ARG) |
3379 |
C |
3380 |
DO 9000 I = 1,IRUN |
3381 |
VPSIM(I) = 0. |
3382 |
VPSIH(I) = 0. |
3383 |
VX(I) = 0. |
3384 |
VXS(I) = 0. |
3385 |
VY(I) = 0. |
3386 |
VYS(I) = 0. |
3387 |
ZZ0(I) = VZH(I)*VZZ(I) |
3388 |
9000 CONTINUE |
3389 |
IBIT = 0 |
3390 |
DO 9122 I = 1,IRUN |
3391 |
IF(VZZ(I).LE.-1.e-7)IBIT = IBIT + 1 |
3392 |
9122 CONTINUE |
3393 |
DO 9022 I = 1,IRUN |
3394 |
IF(VZZ(I).LE.-1.e-7)THEN |
3395 |
INTSTB(I) = 1 |
3396 |
ELSE |
3397 |
INTSTB(I) = 0 |
3398 |
ENDIF |
3399 |
9022 CONTINUE |
3400 |
C |
3401 |
C **************************************** |
3402 |
C ***** UNSTABLE SURFACE LAYER ***** |
3403 |
C **************************************** |
3404 |
C |
3405 |
IF(IBIT.LE.0) GO TO 100 |
3406 |
C |
3407 |
indx = 0 |
3408 |
DO 9002 I = 1,IRUN |
3409 |
IF (INTSTB(I).EQ.1)THEN |
3410 |
indx = indx + 1 |
3411 |
Z(indx) = VZZ(I) |
3412 |
Z0(indx) = ZZ0(I) |
3413 |
ENDIF |
3414 |
9002 CONTINUE |
3415 |
C |
3416 |
DO 9004 I = 1,IBIT |
3417 |
Z(I) = -18. * Z(I) |
3418 |
Z0(I) = -18. * Z0(I) |
3419 |
9004 CONTINUE |
3420 |
|
3421 |
CALL PHI( Z,X1,Y1,IFLAG,IBIT ) |
3422 |
CALL PHI( Z0,X0,Y0,IFLAG,IBIT ) |
3423 |
|
3424 |
C **************************** |
3425 |
C ***** COMPUTE PSIM ***** |
3426 |
C **************************** |
3427 |
C |
3428 |
IF(IFLAG.GE.3) GO TO 75 |
3429 |
C |
3430 |
DO 9006 I = 1,IBIT |
3431 |
ARG1(I) = 1. - X1(I) |
3432 |
IF ( Z(I) .LT. 0.013 ) ARG1(I) = |
3433 |
1 Z(I) * ( 0.25 - 0.09375 * Z(I) ) |
3434 |
C |
3435 |
ARG0(I) = 1. - X0(I) |
3436 |
IF ( Z0(I) .LT. 0.013 ) ARG0(I) = |
3437 |
1 Z0(I) * ( 0.25 - 0.09375 * Z0(I) ) |
3438 |
C |
3439 |
ARG1(I) = ARG1(I) * ( 1.+X0(I) ) |
3440 |
ARG0(I) = ARG0(I) * ( 1.+X1(I) ) |
3441 |
DX(I) = X1(I) - X0(I) |
3442 |
ARG1(I) = ARG1(I) / ARG0(I) |
3443 |
ARG0(I) = -DX(I) / ( 1. + X1(I)*X0(I) ) |
3444 |
ARG0(I) = ATAN( ARG0(I) ) |
3445 |
ARG1(I) = LOG( ARG1(I) ) |
3446 |
PSI2(I) = 2. * ARG0(I) + ARG1(I) |
3447 |
PSI2(I) = PSI2(I) + DX(I) |
3448 |
9006 CONTINUE |
3449 |
C |
3450 |
indx = 0 |
3451 |
DO 9008 I = 1,IRUN |
3452 |
IF( INTSTB(I).EQ.1 ) THEN |
3453 |
indx = indx + 1 |
3454 |
VPSIM(I) = PSI2(indx) |
3455 |
VX(I) = X1(indx) |
3456 |
VXS(I) = X0(indx) |
3457 |
ENDIF |
3458 |
9008 CONTINUE |
3459 |
C |
3460 |
C **************************** |
3461 |
C ***** COMPUTE PSIH ***** |
3462 |
C **************************** |
3463 |
C |
3464 |
IF(IFLAG.EQ.2) GO TO 100 |
3465 |
C |
3466 |
75 CONTINUE |
3467 |
DO 9010 I = 1,IBIT |
3468 |
ARG1(I) = 1. - Y1(I) |
3469 |
IF( Z(I) .LT. 0.0065 ) ARG1(I) = |
3470 |
1 Z(I) * ( 0.5 - 0.625 * Z(I) ) |
3471 |
C |
3472 |
ARG0(I) = 1. - Y0(I) |
3473 |
IF( Z0(I) .LT. 0.0065 ) ARG0(I) = |
3474 |
1 Z0(I) * ( 0.5 - 0.625 * Z0(I) ) |
3475 |
C |
3476 |
ARG1(I) = ARG1(I) * ( 1. + Y0(I) ) |
3477 |
ARG0(I) = ARG0(I) * ( 1. + Y1(I) ) |
3478 |
ARG1(I) = ARG1(I) / ARG0(I) |
3479 |
PSI2(I) = LOG( ARG1(I) ) |
3480 |
PSI2(I) = PSI2(I) - Y1(I) + Y0(I) |
3481 |
9010 CONTINUE |
3482 |
C |
3483 |
indx = 0 |
3484 |
DO 9012 I = 1,IRUN |
3485 |
IF( INTSTB(I).EQ.1 ) THEN |
3486 |
indx = indx + 1 |
3487 |
VPSIH(I) = PSI2(indx) |
3488 |
VY(I) = Y1(indx) |
3489 |
VYS(I) = Y0(indx) |
3490 |
ENDIF |
3491 |
9012 CONTINUE |
3492 |
C |
3493 |
C ************************************** |
3494 |
C ***** STABLE SURFACE LAYER ***** |
3495 |
C ************************************** |
3496 |
C |
3497 |
100 CONTINUE |
3498 |
IBIT = 0 |
3499 |
DO 9114 I = 1,IRUN |
3500 |
IF(VZZ(I).GT.-1.e-7)THEN |
3501 |
IBIT = IBIT + 1 |
3502 |
ENDIF |
3503 |
9114 CONTINUE |
3504 |
DO 9014 I = 1,IRUN |
3505 |
IF(VZZ(I).GT.-1.e-7)THEN |
3506 |
INTSTB(I) = 1 |
3507 |
ELSE |
3508 |
INTSTB(I) = 0 |
3509 |
ENDIF |
3510 |
9014 CONTINUE |
3511 |
IF(IBIT.LE.0) GO TO 300 |
3512 |
indx = 0 |
3513 |
#ifdef CRAY |
3514 |
CDIR$ NOVECTOR |
3515 |
#endif |
3516 |
DO 9016 I = 1,IRUN |
3517 |
IF (INTSTB(I).EQ.1)THEN |
3518 |
indx = indx + 1 |
3519 |
Z(indx) = VZZ(I) |
3520 |
Z0(indx) = ZZ0(I) |
3521 |
ARG1(indx) = VZH(I) |
3522 |
ENDIF |
3523 |
9016 CONTINUE |
3524 |
#ifdef CRAY |
3525 |
CDIR$ VECTOR |
3526 |
#endif |
3527 |
|
3528 |
DO 9018 I = 1,IBIT |
3529 |
HZ(I) = 1. / ARG1(I) |
3530 |
Z1(I) = Z(I) |
3531 |
Z2(I) = ZWM |
3532 |
C |
3533 |
IF ( Z(I) .GT. ZWM ) THEN |
3534 |
Z1(I) = ZWM |
3535 |
Z2(I) = Z(I) |
3536 |
ENDIF |
3537 |
C |
3538 |
IF ( Z0(I) .GT. Z0M ) THEN |
3539 |
Z0(I) = Z0M |
3540 |
INTZ0(I) = 1 |
3541 |
ELSE |
3542 |
INTZ0(I) = 0 |
3543 |
ENDIF |
3544 |
C |
3545 |
X1NUM(I) = 1. + 5. * Z1(I) |
3546 |
X0NUM(I) = 1. + 5. * Z0(I) |
3547 |
X1DEN(I) = 1. / (1. + CM1 * (X1NUM(I) * Z1(I)) ) |
3548 |
X0DEN(I) = 1. + CM1 * (X0NUM(I) * Z0(I)) |
3549 |
C |
3550 |
IF ( (INTZ0(I).EQ.1) .OR. (Z(I).GT.ZWM) ) |
3551 |
1 HZ(I) = Z1(I) / Z0(I) |
3552 |
ARG1(I) = HZ(I)*HZ(I)*X0DEN(I)*X1DEN(I) |
3553 |
ARG1(I) = LOG( ARG1(I) ) |
3554 |
ARG1(I) = 0.5 * ARG1(I) |
3555 |
ARG0(I) = (Z1(I) + 0.1) * (Z0(I) + 0.1) |
3556 |
ARG0(I) = CM3 + ARG0(I) * CM4 |
3557 |
ARG0(I) = ( Z1(I) - Z0(I) ) / ARG0(I) |
3558 |
ARG0(I) = ATAN( ARG0(I) ) |
3559 |
TEMP(I) = ARG1(I) + CM5 * ARG0(I) |
3560 |
C |
3561 |
X0(I) = X0NUM(I) / X0DEN(I) |
3562 |
IF ( INTZ0(I).EQ.1 ) X0(I) = 0. |
3563 |
Z2ZWM(I) = Z2(I) * RZWM |
3564 |
9018 CONTINUE |
3565 |
C |
3566 |
C **************************** |
3567 |
C ***** COMPUTE PSIM ***** |
3568 |
C **************************** |
3569 |
C |
3570 |
IF( IFLAG.GE.3 ) GO TO 225 |
3571 |
C |
3572 |
DO 9020 I = 1,IBIT |
3573 |
X1(I) = X1NUM(I) * X1DEN(I) |
3574 |
ARG1(I) = LOG( Z2ZWM(I) ) |
3575 |
PSI2(I) = TEMP(I) + CM6 * ARG1(I) |
3576 |
9020 CONTINUE |
3577 |
C |
3578 |
indx = 0 |
3579 |
DO 9030 I = 1,IRUN |
3580 |
IF( INTSTB(I).EQ.1 ) THEN |
3581 |
indx = indx + 1 |
3582 |
VPSIM(I) = PSI2(indx) |
3583 |
VX(I) = X1(indx) |
3584 |
VXS(I) = X0(indx) |
3585 |
ENDIF |
3586 |
9030 CONTINUE |
3587 |
C |
3588 |
C **************************** |
3589 |
C ***** COMPUTE PSIH ***** |
3590 |
C **************************** |
3591 |
C |
3592 |
IF(IFLAG.EQ.2)GO TO 300 |
3593 |
C |
3594 |
225 CONTINUE |
3595 |
DO 9024 I = 1,IBIT |
3596 |
Y1DEN(I) = 1. + CM1 * ( X1NUM(I) * Z(I) ) |
3597 |
Y1(I) = X1NUM(I) / Y1DEN(I) |
3598 |
ARG1(I) = CM7 * Z2ZWM(I) / ( CM2 + Z2(I) ) |
3599 |
ARG0(I) = 6. |
3600 |
IF ( Z2(I) .GT. ZCM ) THEN |
3601 |
Y1(I) = YCM |
3602 |
ARG1(I) = Z2(I) * RZCM |
3603 |
ARG0(I) = YCM |
3604 |
TEMP(I) = TEMP(I) + CM8 |
3605 |
ENDIF |
3606 |
ARG1(I) = LOG( ARG1(I) ) |
3607 |
PSI2(I) = TEMP(I) + ARG0(I) * ARG1(I) |
3608 |
9024 CONTINUE |
3609 |
C |
3610 |
indx = 0 |
3611 |
DO 9026 I = 1,IRUN |
3612 |
IF( INTSTB(I).EQ.1 ) THEN |
3613 |
indx = indx + 1 |
3614 |
VPSIH(I) = PSI2(indx) |
3615 |
VY(I) = Y1(indx) |
3616 |
VYS(I) = X0(indx) |
3617 |
ENDIF |
3618 |
9026 CONTINUE |
3619 |
C |
3620 |
300 CONTINUE |
3621 |
C |
3622 |
RETURN |
3623 |
END |
3624 |
SUBROUTINE TRBLEN (STRT,DW2,DZ3,Q,VKZE,VKZM,DTHV,DPK,DU,DV,XL, |
3625 |
1 QXLM,NLEV,INIT,LMIN,LMINQ,LMINQ1,CP,INT1,INT2, |
3626 |
2 DZITRP,STBFCN,XL0,Q1,WRKIT1,WRKIT2,WRKIT3,WRKIT4,irun) |
3627 |
C********************************************************************** |
3628 |
C |
3629 |
C SUBROUTINE TRBLEN - COMPUTES TURBULENT LENGTH SCALE |
3630 |
C - CALLED FROM TRBFLX |
3631 |
C ARGUMENTS :: |
3632 |
C |
3633 |
C INPUT: |
3634 |
C ------ |
3635 |
C STRT - BRUNT VAISALA FREQUENCY |
3636 |
C DW2 - SQUARED SHEAR |
3637 |
C DZ3 - LAYER THICKNESS FOR LENGTH SCALE CALC. |
3638 |
C Q - TURBULENCE VELOCITY |
3639 |
C VKZE - VK * Z AT LAYER EDGES |
3640 |
C VKZM - VK * Z AT LAYER CENTERS |
3641 |
C DTHV - VERTICAL GRADIENT OF THV |
3642 |
C DPK - VERTICAL GRADIENT OF PK |
3643 |
C DU - VERTICAL GRADIENT OF U |
3644 |
C DV - VERTICAL GRADIENT OF V |
3645 |
C NLEV - NUMBER OF ATMOSPHERIC LEVELS |
3646 |
C INIT - INPUT FLAG : 1 = INITIAL START |
3647 |
C 2 = 2ND CALL FOR INITIAL STAR |
3648 |
C 0 = NON-INITIAL START |
3649 |
C |
3650 |
C OUTPUT: |
3651 |
C ------- |
3652 |
C XL - TURBULENT LENGTH SCALE |
3653 |
C QXLM - TURBULENT LENGTH SCALE * Q AT LAYER CENTER |
3654 |
C LMIN - HIGHEST LAYER WHERE INSTABILITY OCCURS |
3655 |
C LMINQ - HIGHEST LAYER WHERE TURBULENCE OCCURS |
3656 |
C |
3657 |
C SUBPROGRAMS NEEDED :: |
3658 |
C |
3659 |
C TRBITP - INTERPOLATES TO HEIGHT WHERE RI = RICR |
3660 |
C |
3661 |
C********************************************************************** |
3662 |
implicit none |
3663 |
|
3664 |
C Argument List Declarations |
3665 |
integer irun,nlev,init,lmin,lminq,lminq1 |
3666 |
_RL cp |
3667 |
_RL STRT(irun,NLEV),DW2(irun,NLEV),DZ3(irun,NLEV) |
3668 |
_RL Q(irun,NLEV),VKZM(irun,NLEV-1),VKZE(irun,NLEV-1) |
3669 |
_RL DTHV(irun,NLEV),DPK(irun,NLEV),DU(irun,NLEV) |
3670 |
_RL DV(irun,NLEV) |
3671 |
_RL QXLM(irun,NLEV-1),XL(irun,NLEV-1) |
3672 |
_RL DZITRP(irun,nlev-1),STBFCN(irun,nlev) |
3673 |
_RL XL0(irun,nlev),Q1(irun,nlev-1) |
3674 |
_RL WRKIT1(irun,nlev-1),WRKIT2(irun,nlev-1) |
3675 |
_RL WRKIT3(irun,nlev-1) |
3676 |
_RL WRKIT4(irun,nlev-1) |
3677 |
INTEGER INT1(irun,nlev), INT2(irun,nlev-1) |
3678 |
|
3679 |
C Local Variables |
3680 |
_RL rf1,rf2,e5,d4,d1,rfc,ricr,alpha,dzcnv,xl0cnv,xl0min |
3681 |
_RL clmt,clmt53 |
3682 |
PARAMETER ( RF1 = 0.2340678 ) |
3683 |
PARAMETER ( RF2 = 0.2231172 ) |
3684 |
PARAMETER ( E5 = 49.66 ) |
3685 |
PARAMETER ( D4 = 2.6532122E-2 ) |
3686 |
PARAMETER ( D1 = D4 * E5 ) |
3687 |
PARAMETER ( RFC = 0.1912323 ) |
3688 |
PARAMETER ( RICR = ( (RF1-RFC)*RFC ) / ( (RF2-RFC)*D1 ) ) |
3689 |
PARAMETER ( ALPHA = 0.1 ) |
3690 |
PARAMETER ( DZCNV = 100. ) |
3691 |
PARAMETER ( XL0CNV = DZCNV * ALPHA ) |
3692 |
PARAMETER ( XL0MIN = 1. ) |
3693 |
PARAMETER ( CLMT = 0.23 ) |
3694 |
PARAMETER ( CLMT53 = 5. * CLMT / 3. ) |
3695 |
|
3696 |
integer ibit,nlevm1,nlevp1,istnlv,istnm1,nlevml,istnml,Lp1 |
3697 |
integer istnmq,istlmq,lminp,lm1,lmin1 |
3698 |
integer i,L,LL |
3699 |
C |
3700 |
NLEVM1 = NLEV - 1 |
3701 |
NLEVP1 = NLEV + 1 |
3702 |
ISTNLV = irun * NLEV |
3703 |
ISTNM1 = irun * NLEVM1 |
3704 |
C |
3705 |
IF ( INIT.EQ.2 ) GO TO 1200 |
3706 |
C |
3707 |
C COMPUTE DEPTHS OF UNSTABLE LAYERS |
3708 |
C ================================= |
3709 |
DO 10 I=1,ISTNLV |
3710 |
STBFCN(I,1) = STRT(I,1) - RICR * DW2(I,1) |
3711 |
INT1(I,1) = 0 |
3712 |
IF( STBFCN(I,1).LE.0. ) INT1(I,1) = 1 |
3713 |
10 CONTINUE |
3714 |
DO 20 I=1,ISTNM1 |
3715 |
INT2(I,1) = 0 |
3716 |
IF( INT1(I,1).EQ.1 .XOR. INT1(I,2).EQ.1 ) INT2(I,1) = 1 |
3717 |
20 CONTINUE |
3718 |
C |
3719 |
DO 40 LMIN = 1,NLEV |
3720 |
IBIT = 0 |
3721 |
DO 30 I=1,irun |
3722 |
IBIT = IBIT + INT1(I,LMIN) |
3723 |
30 CONTINUE |
3724 |
IF(IBIT.GE.1) GO TO 50 |
3725 |
40 CONTINUE |
3726 |
LMIN = NLEVP1 |
3727 |
50 CONTINUE |
3728 |
LMIN = 1 |
3729 |
C |
3730 |
DO 60 I=1,ISTNM1 |
3731 |
XL0(I,1) = 0. |
3732 |
60 CONTINUE |
3733 |
DO 70 I=1,irun |
3734 |
XL0(I,NLEV) = DZ3(I,NLEV) |
3735 |
70 CONTINUE |
3736 |
C |
3737 |
IF(LMIN.GE.NLEVP1) GOTO 1100 |
3738 |
LMIN1 = LMIN - 1 |
3739 |
IF(LMIN1.EQ.0) LMIN1 = 1 |
3740 |
NLEVML = NLEV - LMIN1 |
3741 |
ISTNML = irun*NLEVML |
3742 |
CALL TRBITP ( STBFCN(1,LMIN1),INT2(1,LMIN1),DTHV(1,LMIN1), |
3743 |
. DPK(1,LMIN1), DU(1,LMIN1), DV(1,LMIN1), |
3744 |
. DZITRP(1,LMIN1), NLEVML, |
3745 |
. WRKIT1,WRKIT2,WRKIT3,WRKIT4,CP,irun ) |
3746 |
LP1 = LMIN1 + 1 |
3747 |
C |
3748 |
DO 80 I=1,ISTNML |
3749 |
INT2(I,LMIN1) = 0 |
3750 |
IF( INT1(I,LMIN1).EQ.1 .OR. INT1(I,LP1).EQ.1 ) INT2(I,LMIN1) = 1 |
3751 |
IF( INT2(I,LMIN1).EQ.1 ) |
3752 |
. XL0(I,LMIN1) = (0.5+DZITRP(I,LMIN1)) * DZ3(I,LP1) |
3753 |
80 CONTINUE |
3754 |
DO 90 I=1,irun |
3755 |
INT2(I,NLEVM1) = INT1(I,NLEV) |
3756 |
90 CONTINUE |
3757 |
C |
3758 |
DO 100 I=1,ISTNML |
3759 |
IF( INT2(I,LMIN1).EQ.1 ) THEN |
3760 |
XL0(I,LP1) = XL0(I,LP1) + ( (0.5-DZITRP(I,LMIN1)) * DZ3(I,LP1) ) |
3761 |
ENDIF |
3762 |
100 CONTINUE |
3763 |
IF (LMIN.GT.1) GOTO 400 |
3764 |
DO 110 I=1,irun |
3765 |
IF( INT1(I,1).EQ.1 ) XL0(I,1) = XL0(I,1) + DZ3(I,1) |
3766 |
110 CONTINUE |
3767 |
400 CONTINUE |
3768 |
C |
3769 |
LMINP = LMIN + 1 |
3770 |
IF(LMINP.GT.NLEVM1) GOTO 550 |
3771 |
DO 500 L = LMINP,NLEVM1 |
3772 |
LM1 = L-1 |
3773 |
DO 120 I = 1,irun |
3774 |
IF( INT1(I,LM1).EQ.1 ) XL0(I,L) = XL0(I,L) + XL0(I,LM1) |
3775 |
120 CONTINUE |
3776 |
500 CONTINUE |
3777 |
550 CONTINUE |
3778 |
IF(LMIN.GT.NLEVM1) GOTO 600 |
3779 |
DO 130 I = 1,irun |
3780 |
IF( INT1(I,NLEVM1).EQ.1 .AND. INT1(I,NLEV).EQ.1 ) THEN |
3781 |
XL0(I,NLEV) = XL0(I,NLEV) + XL0(I,NLEVM1) |
3782 |
ENDIF |
3783 |
130 CONTINUE |
3784 |
IF(LMIN.GT.NLEV) GOTO 1100 |
3785 |
600 CONTINUE |
3786 |
DO 1000 LL = LMIN,NLEV-1 |
3787 |
L = NLEVM1 + LMIN - LL |
3788 |
LP1 = L+1 |
3789 |
DO 140 I = 1,irun |
3790 |
IF( INT1(I,LP1).EQ.1 ) THEN |
3791 |
IF( INT1(I,L) .EQ.1 ) THEN |
3792 |
XL0(I,L) = XL0(I,LP1) |
3793 |
ELSE |
3794 |
XL0(I,L) = XL0(I,L) + XL0(I,LP1) |
3795 |
ENDIF |
3796 |
ENDIF |
3797 |
140 CONTINUE |
3798 |
1000 CONTINUE |
3799 |
1100 CONTINUE |
3800 |
C |
3801 |
DO 150 I = 1,ISTNLV |
3802 |
IF( XL0(I,1).LT.XL0CNV ) XL0(I,1) = XL0CNV |
3803 |
150 CONTINUE |
3804 |
C |
3805 |
C ********************************************************************* |
3806 |
C **** DETERMINE MIXING LENGTHS FOR STABLE LAYERS *** |
3807 |
C ********************************************************************* |
3808 |
C |
3809 |
IF(INIT.EQ.1) GOTO 1400 |
3810 |
C |
3811 |
IF(LMINQ.GT.1) THEN |
3812 |
ISTLMQ = irun * LMINQ1 |
3813 |
DO 160 I = 1,ISTLMQ |
3814 |
INT2(I,1) = 1 - INT1(I,1) |
3815 |
160 CONTINUE |
3816 |
ENDIF |
3817 |
IF(LMINQ.LT.NLEV) THEN |
3818 |
ISTNMQ = irun * (NLEV-LMINQ) |
3819 |
DO 170 I = 1,ISTNMQ |
3820 |
IF( INT1(I,LMINQ).EQ.0 ) THEN |
3821 |
XL0(I,LMINQ) = Q(I,LMINQ) / XL0(I,LMINQ) |
3822 |
XL0(I,LMINQ) = XL0(I,LMINQ) * XL0(I,LMINQ) + 1.0E-20 |
3823 |
XL0(I,LMINQ) = STBFCN(I,LMINQ) + XL0(I,LMINQ) |
3824 |
XL0(I,LMINQ) = SQRT( XL0(I,LMINQ) ) |
3825 |
XL0(I,LMINQ) = Q(I,LMINQ) / XL0(I,LMINQ) |
3826 |
ENDIF |
3827 |
INT2(I,LMINQ) = 0 |
3828 |
IF( XL0(I,LMINQ).LT.XL0MIN ) INT2(I,LMINQ) = 1 |
3829 |
170 CONTINUE |
3830 |
ENDIF |
3831 |
C |
3832 |
1200 CONTINUE |
3833 |
C |
3834 |
IF(INIT.EQ.2) THEN |
3835 |
DO 180 I = 1,ISTNM1 |
3836 |
INT2(I,1) = 1 - INT1(I,1) |
3837 |
180 CONTINUE |
3838 |
ENDIF |
3839 |
DO 190 I = 1,ISTNM1 |
3840 |
IF( INT2(I,1).EQ.1 ) XL0(I,1) = XL0MIN |
3841 |
190 CONTINUE |
3842 |
C |
3843 |
C ********************************************************************* |
3844 |
C **** LENGTH SCALE XL FROM XL0 AND VKZE **** |
3845 |
C ********************************************************************* |
3846 |
C |
3847 |
1400 CONTINUE |
3848 |
C |
3849 |
DO 200 I = 1,ISTNM1 |
3850 |
XL(I,1) = XL0(I,1) * VKZE(I,1) / ( XL0(I,1)+VKZE(I,1) ) |
3851 |
200 CONTINUE |
3852 |
C |
3853 |
C ********************************************************************* |
3854 |
C **** CLMT53 TIMES Q TIMES LENGTH SCALE AT MID LEVELS *** |
3855 |
C ********************************************************************* |
3856 |
C |
3857 |
IF(INIT.EQ.1) GOTO 1700 |
3858 |
ISTNMQ = irun * (NLEV-LMINQ1) |
3859 |
DO 210 I = 1,ISTNMQ |
3860 |
Q1(I,LMINQ1) = Q(I,LMINQ1) |
3861 |
INT1(I,LMINQ1) = 0 |
3862 |
IF( Q(I,LMINQ1).LE.Q(I,LMINQ1+1) ) INT1(I,LMINQ1) = 1 |
3863 |
IF( INT1(I,LMINQ1).EQ.1 ) THEN |
3864 |
XL0(I,LMINQ1) = XL0(I,LMINQ1+1) |
3865 |
Q1(I,LMINQ1) = Q(I,LMINQ1+1) |
3866 |
ENDIF |
3867 |
210 CONTINUE |
3868 |
C |
3869 |
DO 240 I = 1,ISTNMQ |
3870 |
QXLM(I,LMINQ1) = XL0(I,LMINQ1)*VKZM(I,LMINQ1) |
3871 |
. / ( XL0(I,LMINQ1)+VKZM(I,LMINQ1) ) |
3872 |
QXLM(I,LMINQ1) = CLMT53 * Q1(I,LMINQ1)*QXLM(I,LMINQ1) |
3873 |
240 CONTINUE |
3874 |
C |
3875 |
1700 CONTINUE |
3876 |
C |
3877 |
RETURN |
3878 |
END |
3879 |
SUBROUTINE TRBITP ( STBFCN,INTCHG,DTHV,DPK,DU,DV,DZITRP,NLEV, |
3880 |
. AAA,BBB,CCC,DDD,CP,irun ) |
3881 |
C********************************************************************** |
3882 |
C |
3883 |
C SUBROUTINE TRBITP - INTERPOLATES TO THE HEIGHT WHERE RI EQUALS RICR |
3884 |
C - CALLED FROM TRBLEN |
3885 |
C ARGUMENTS :: |
3886 |
C |
3887 |
C INPUT: |
3888 |
C ------ |
3889 |
C STBFCN - DTHV * DPK - RICR*( DU*DU + DV*DV) |
3890 |
C INTCHG - INT '1' AT LEVELS WHERE STBFCN CHANGES SIG |
3891 |
C DTHV - VERTICAL GRADIENT OF THV |
3892 |
C DPK - VERTICAL GRADIENT OF PK |
3893 |
C DU - VERTICAL GRADIENT OF U |
3894 |
C DV - VERTICAL GRADIENT OF V |
3895 |
C NLEV - NUMBER OF LEVELS TO BE PROCESSED |
3896 |
C |
3897 |
C OUTPUT: |
3898 |
C ------- |
3899 |
C DZITRP - INTERPOLATION COEFFICIENT |
3900 |
C |
3901 |
C********************************************************************** |
3902 |
implicit none |
3903 |
|
3904 |
C Argument List Declarations |
3905 |
integer irun,nlev |
3906 |
_RL cp |
3907 |
_RL STBFCN(irun,NLEV+1) |
3908 |
integer INTCHG(irun,NLEV) |
3909 |
_RL DTHV(irun,NLEV+1),DPK(irun,NLEV+1) |
3910 |
_RL DU(irun,NLEV+1),DV(irun,NLEV+1) |
3911 |
_RL DZITRP(irun,NLEV+1) |
3912 |
_RL AAA(irun,NLEV),BBB(irun,NLEV) |
3913 |
_RL CCC(irun,NLEV),DDD(irun,NLEV) |
3914 |
|
3915 |
C Local Variables |
3916 |
_RL rf1,rf2,e5,d4,d1,rfc,ricr |
3917 |
PARAMETER ( RF1 = 0.2340678 ) |
3918 |
PARAMETER ( RF2 = 0.2231172 ) |
3919 |
PARAMETER ( E5 = 49.66 ) |
3920 |
PARAMETER ( D4 = 2.6532122E-2 ) |
3921 |
PARAMETER ( D1 = D4 * E5 ) |
3922 |
PARAMETER ( RFC = 0.1912323 ) |
3923 |
PARAMETER ( RICR = ( (RF1-RFC)*RFC ) / ( (RF2-RFC)*D1 ) ) |
3924 |
|
3925 |
integer istnlv |
3926 |
integer i |
3927 |
C |
3928 |
C ********************************************************************* |
3929 |
C **** QUADRATIC INTERPOLATION OF RI TO RICR VIA *** |
3930 |
C **** LINEAR INTERPOLATION OF DTHV, DPK, DU & DV *** |
3931 |
C ********************************************************************* |
3932 |
C |
3933 |
ISTNLV = irun*NLEV |
3934 |
DO 10 I=1,ISTNLV |
3935 |
DZITRP(I,1) = 0. |
3936 |
10 CONTINUE |
3937 |
DO 20 I=1,ISTNLV |
3938 |
IF( INTCHG(I,1).EQ.1 ) THEN |
3939 |
DDD(I,1) = ( CP *(DTHV(I,2)*DPK(I,1) |
3940 |
. + DTHV(I,1)*DPK(I,2)) ) |
3941 |
. - ( (2.*RICR) * ( DU(I,2)* DU(I,1) |
3942 |
. + DV(I,2)* DV(I,1)) ) |
3943 |
AAA(I,1) = STBFCN(I,1) + STBFCN(I,2) |
3944 |
BBB(I,1) = STBFCN(I,1) - STBFCN(I,2) |
3945 |
CCC(I,1) = 1. / BBB(I,1) |
3946 |
DZITRP(I,1) = AAA(I,1) * CCC(I,1) |
3947 |
AAA(I,1) = AAA(I,1) - DDD(I,1) |
3948 |
DDD(I,1) = ( DDD(I,1) * DDD(I,1) ) |
3949 |
. - 4. * (STBFCN(I,2) * STBFCN(I,1) ) |
3950 |
DDD(I,1) = DDD(I,1)*CCC(I,1)*CCC(I,1) |
3951 |
DDD(I,1) = SQRT( DDD(I,1) ) |
3952 |
ENDIF |
3953 |
C |
3954 |
IF( INTCHG(I,1).EQ.1 .AND. AAA(I,1).NE.0. ) THEN |
3955 |
DZITRP(I,1) = ( BBB(I,1)*(1.-DDD(I,1)) ) / AAA(I,1) |
3956 |
ENDIF |
3957 |
C |
3958 |
DZITRP(I,1) = 0.5 * DZITRP(I,1) |
3959 |
20 CONTINUE |
3960 |
C |
3961 |
RETURN |
3962 |
END |
3963 |
SUBROUTINE TRBL20 (RI,STRT,DW2,XL,ZKM,ZKH,QE,QQE,INTSTB,NLEV, |
3964 |
1 nlay,irun) |
3965 |
C********************************************************************** |
3966 |
C |
3967 |
C SUBROUTINE TRBL20 - COMPUTES QE AND DIMLESS COEFS FROM |
3968 |
C MELLOR-YAMADA LEVEL 2 MODEL |
3969 |
C - CALLED FROM AND FROM TRBFLX |
3970 |
C ARGUMENTS :: |
3971 |
C |
3972 |
C INPUT: |
3973 |
C ------ |
3974 |
C RI - RICHARDSON NUMBER |
3975 |
C STRT - BRUNT VAISALA FREQUENCY |
3976 |
C DW2 - SQUARED SHEAR |
3977 |
C XL - TURBULENT LENGTH SCALE |
3978 |
C NLEV - NUMBER OF LEVELS TO BE PROCESSED |
3979 |
C |
3980 |
C OUTPUT: |
3981 |
C ------- |
3982 |
C ZKM - MOMENTUM TRANSPORT COEFFICIENT |
3983 |
C ZKH - HEAT TRANSPORT COEFFICIENT |
3984 |
C QE - EQUILIBRIUM TURBULENT VELOCITY SCALE |
3985 |
C QQE - EQUILIBRIUM TURBULENT KINETIC ENERGY |
3986 |
C BITSTB - BIT '1' WHERE QE GREATER THAN ZERO |
3987 |
C |
3988 |
C********************************************************************** |
3989 |
implicit none |
3990 |
|
3991 |
C Argument List Declarations |
3992 |
integer nlev,nlay,irun |
3993 |
_RL RI(irun,NLEV),STRT(irun,NLEV),DW2(irun,NLEV) |
3994 |
_RL XL(irun,NLEV),ZKM(irun,NLEV),ZKH(irun,NLEV) |
3995 |
_RL QE(irun,NLEV),QQE(irun,NLEV) |
3996 |
INTEGER INTSTB(irun,nlev) |
3997 |
_RL EE(irun,nlay-1),RF(irun,nlay-1) |
3998 |
|
3999 |
C Local Variables |
4000 |
_RL b1,b2,d3,rf1,rf2,d3b2,d2,e5,d4,d1,d1half,d2half |
4001 |
_RL rfc,ricr,ch,cm |
4002 |
PARAMETER ( B1 = 16.6 ) |
4003 |
PARAMETER ( B2 = 10.1 ) |
4004 |
PARAMETER ( D3 = 0.29397643 ) |
4005 |
PARAMETER ( RF1 = 0.2340678 ) |
4006 |
PARAMETER ( RF2 = 0.2231172 ) |
4007 |
PARAMETER ( D3B2 = D3 / RF1 ) |
4008 |
PARAMETER ( D2 = RF1 ) |
4009 |
PARAMETER ( E5 = 49.66 ) |
4010 |
PARAMETER ( D4 = 2.6532122E-2 ) |
4011 |
PARAMETER ( D1 = D4 * E5 ) |
4012 |
PARAMETER ( D1HALF = 0.5 * D1 ) |
4013 |
PARAMETER ( D2HALF = 0.5 * D2 ) |
4014 |
PARAMETER ( RFC = 0.1912323 ) |
4015 |
PARAMETER ( RICR = ( (RF1-RFC)*RFC ) / ( (RF2-RFC)*D1 ) ) |
4016 |
PARAMETER ( CH = 2.5828674 ) |
4017 |
PARAMETER ( CM = CH / D1 ) |
4018 |
|
4019 |
integer istnlv |
4020 |
integer i |
4021 |
|
4022 |
ISTNLV = irun * NLEV |
4023 |
C |
4024 |
C ********************************************************************* |
4025 |
C **** COMPUTE FLUX RICHARDSON NUMBER *** |
4026 |
C ********************************************************************* |
4027 |
C |
4028 |
DO 10 I=1,ISTNLV |
4029 |
EE(I,1) = D1HALF * RI(I,1) + D2HALF |
4030 |
RF(I,1) = EE(I,1)* EE(I,1) |
4031 |
RF(I,1) = RF(I,1)- D3*RI(I,1) |
4032 |
RF(I,1) = SQRT( RF(I,1) ) |
4033 |
RF(I,1) = EE(I,1) - RF(I,1) |
4034 |
C |
4035 |
IF( RI(I,1).LE.1.e-4 .AND. RI(I,1).GE.-1.e-4 ) THEN |
4036 |
RF(I,1) = D3B2*RI(I,1) |
4037 |
ENDIF |
4038 |
C |
4039 |
C ********************************************************************* |
4040 |
C **** QE AND DIMENSIONLESS DIFFUSION COEFICIENTS *** |
4041 |
C **** FROM LEVEL 2 CLOSURE MODEL *** |
4042 |
C ********************************************************************* |
4043 |
C |
4044 |
IF( RI(I,1).LT.RICR .AND. RF(I,1).LT.RFC ) THEN |
4045 |
ZKH(I,1) = ( RFC-RF(I,1) ) / (1.-RF(I,1)) |
4046 |
ZKM(I,1) = CM * (RF1-RF(I,1)) |
4047 |
ZKM(I,1) = ZKH(I,1)*ZKM(I,1) / (RF2-RF(I,1)) |
4048 |
ZKH(I,1) = CH *ZKH(I,1) |
4049 |
QE(I,1) = ZKM(I,1)*DW2(I,1) - ZKH(I,1)*STRT(I,1) |
4050 |
ENDIF |
4051 |
C |
4052 |
IF( QE(I,1).LT.1.e-14 ) THEN |
4053 |
INTSTB(I,1) = 0 |
4054 |
QE(I,1) = 0. |
4055 |
ELSE |
4056 |
INTSTB(I,1) = 1 |
4057 |
QE(I,1) = B1*QE(I,1) |
4058 |
QE(I,1) = SQRT( QE(I,1) ) |
4059 |
QE(I,1) = XL(I,1)*QE(I,1) |
4060 |
ENDIF |
4061 |
QQE(I,1) = 0.5 * QE(I,1) * QE(I,1) |
4062 |
10 CONTINUE |
4063 |
C |
4064 |
RETURN |
4065 |
END |
4066 |
SUBROUTINE TRBL25(Q,XL,STRT,DW2,INTSTB,INTQ,ZKM,ZKH,P3,NLEV, |
4067 |
1 nlay,irun) |
4068 |
C********************************************************************** |
4069 |
C |
4070 |
C SUBROUTINE TRBL25 - COMPUTES P3 AND DIMLESS COEFS FROM |
4071 |
C MELLOR-YAMADA LEVEL 2.5 MODEL |
4072 |
C - CALLED FROM TRBFLX |
4073 |
C |
4074 |
C ARGUMENTS :: |
4075 |
C |
4076 |
C INPUT: |
4077 |
C ------ |
4078 |
C Q - TURBULENCE VELOCITY |
4079 |
C XL - TURBULENT LENGTH SCALE |
4080 |
C STRT - BRUNT VAISALA FREQUENCY |
4081 |
C DW2 - SQUARED SHEAR |
4082 |
C BITSTB - BIT '1' WHERE QE GREATER THAN ZERO |
4083 |
C NLEV - NUMBER OF LEVELS TO BE PROCESSED |
4084 |
C |
4085 |
C OUTPUT: |
4086 |
C ------- |
4087 |
C ZKM - MOMENTUM TRANSPORT COEFFICIENT |
4088 |
C ZKH - HEAT TRANSPORT COEFFICIENT |
4089 |
C P3 - PRODUCTION RATE OF TURBULENT KINETIC ENERG |
4090 |
C |
4091 |
C********************************************************************** |
4092 |
implicit none |
4093 |
|
4094 |
C Argument list Declarations |
4095 |
integer nlev,nlay,irun |
4096 |
_RL Q(irun,NLEV),XL(irun,NLEV),STRT(irun,NLEV) |
4097 |
_RL DW2(irun,NLEV) |
4098 |
INTEGER INTSTB(irun,nlay), INTQ(irun,nlay) |
4099 |
_RL ZKM(irun,NLEV),ZKH(irun,NLEV),P3(irun,NLEV) |
4100 |
|
4101 |
C Local Variables |
4102 |
_RL a1,a2,a4,c1,a5,a3,b1,b2,b3,ff2,ff3,ff4 |
4103 |
PARAMETER ( A1 = 0.92 ) |
4104 |
PARAMETER ( A2 = 0.74 ) |
4105 |
PARAMETER ( A4 = 6. * A1 * A1) |
4106 |
PARAMETER ( C1 = 0.08 ) |
4107 |
PARAMETER ( A5 = 3.*C1*(-1.) ) |
4108 |
PARAMETER ( A3 = A4 * A5*(-1.) ) |
4109 |
PARAMETER ( B1 = 16.6 ) |
4110 |
PARAMETER ( B2 = 10.1 ) |
4111 |
PARAMETER ( B3 = 1. / B1 ) |
4112 |
PARAMETER ( FF2 = 9. * A1 * A2 ) |
4113 |
PARAMETER ( FF3 = (3.*A2*B2) - (9.*A2*A2 ) ) |
4114 |
PARAMETER ( FF4 = (3.*A2*B2) + (12.*A1*A2 ) ) |
4115 |
|
4116 |
_RL F2(irun,nlay-1),F3(irun,nlay-1) |
4117 |
_RL F4(irun,nlay-1),XQ(irun,nlay-1) |
4118 |
|
4119 |
integer istnlv |
4120 |
integer i |
4121 |
C |
4122 |
ISTNLV = irun * NLEV |
4123 |
C |
4124 |
C ********************************************************************* |
4125 |
C **** P3 AND DIMENSIONLESS DIFFUSION COEFICIENTS *** |
4126 |
C **** FROM LEVEL 2.5 CLOSURE MODEL *** |
4127 |
C ********************************************************************* |
4128 |
C |
4129 |
DO 10 I=1,ISTNLV |
4130 |
IF( INTQ(I,1).EQ.1 .AND. INTSTB(I,1).EQ.0 ) THEN |
4131 |
XQ(I,1) = XL(I,1) / Q(I,1) |
4132 |
XQ(I,1) = XQ(I,1) * XQ(I,1) |
4133 |
STRT(I,1) = XQ(I,1) * STRT(I,1) |
4134 |
DW2(I,1) = XQ(I,1) * DW2(I,1) |
4135 |
F2(I,1) = 1.+FF2 * STRT(I,1) |
4136 |
F3(I,1) = 1.+FF3 * STRT(I,1) |
4137 |
F4(I,1) = 1.+FF4 * STRT(I,1) |
4138 |
ZKH(I,1) = (F4(I,1) * F2(I,1)) |
4139 |
. + A4 * (F3(I,1) * DW2(I,1)) |
4140 |
ZKH(I,1) = (F2(I,1) + A3*DW2(I,1)) |
4141 |
. / ZKH(I,1) |
4142 |
ZKM(I,1) = A1 * (F3(I,1)*ZKH(I,1)+A5) |
4143 |
. / F2(I,1) |
4144 |
ZKH(I,1) = A2 * ZKH(I,1) |
4145 |
P3(I,1) = ZKH(I,1)*STRT(I,1) + B3 |
4146 |
P3(I,1) = 2. * ( ZKM(I,1)*DW2(I,1) - P3(I,1) ) |
4147 |
P3(I,1) = P3(I,1)*Q(I,1) |
4148 |
C |
4149 |
ENDIF |
4150 |
10 CONTINUE |
4151 |
C |
4152 |
RETURN |
4153 |
END |
4154 |
SUBROUTINE TRBDIF ( XX1,XX2,RHOKDZ,FLXFAC,DXX1G,DXX2G,NLEV, |
4155 |
. ITYPE,EPSL,irun ) |
4156 |
C |
4157 |
C********************************************************************** |
4158 |
C |
4159 |
C ARGUMENTS :: |
4160 |
C |
4161 |
C INPUT: |
4162 |
C ------ |
4163 |
C XX1 - FIRST PROPERTY TO BE DIFFUSED |
4164 |
C (INPUT INCLUDES FORWARD PRODUCTION TERM) |
4165 |
C XX2 - SECOND PROPERTY TO BE DIFFUSED (V-WIND) |
4166 |
C (INPUT INCLUDES FORWARD PRODUCTION TERM) |
4167 |
C -OR- |
4168 |
C CHANGE IN XX1 DUE TO UNIT CHANGE IN THG |
4169 |
C (TH OR SH PROFILES) |
4170 |
C -OR- |
4171 |
C BACKWARD PRODUCTION TERM (QQ) |
4172 |
C RHOKDZ - RHO * K * WEIGHT / DZ AT INTERFACES |
4173 |
C FLXFAC - G * DT / (DP*WEIGHT) AT EDGES |
4174 |
C NLEV - NUMBER OF ATMOSPHERIC LEVELS |
4175 |
C ITYPE - INTEGER FLAG FOR INPUT TYPE |
4176 |
C 1 = QQ: COMPUTE BACKWARD PRODUCTION AND |
4177 |
C USE UNDERFLOW CUTOFF |
4178 |
C 2 = TH OR SH: COMPUTE TENDENCY DUE TO |
4179 |
C SURFACE PERTURBATION |
4180 |
C 3 = U AND V: COMPUTE BOTH FIELDS |
4181 |
C EPSL - UNDERFLOW CUTOFF CRITERION (QQ ONLY) |
4182 |
C |
4183 |
C OUTPUT: |
4184 |
C ------ |
4185 |
C XX1 - NEW VALUE RETURNED |
4186 |
C XX2 - NEW VALUE RETURNED |
4187 |
C DXX1G - SOURCE TERM FOR XX1 AT GROUND |
4188 |
C DXX1G - SOURCE TERM FOR XX2 AT GROUND |
4189 |
C |
4190 |
C********************************************************************** |
4191 |
implicit none |
4192 |
|
4193 |
C Argument List Declarations |
4194 |
integer nlev,itype,irun |
4195 |
_RL XX1(irun,NLEV+1),XX2(irun,NLEV+1) |
4196 |
_RL RHOKDZ(irun,NLEV),FLXFAC(irun,NLEV+1) |
4197 |
_RL DXX1G(irun),DXX2G(irun) |
4198 |
_RL epsl |
4199 |
C |
4200 |
_RL AA(irun,nlev), BB(irun,nlev), CC(irun,nlev+1) |
4201 |
integer istnlv,istnm1,nlevp1,istnlx |
4202 |
integer i |
4203 |
C |
4204 |
ISTNLV = irun * NLEV |
4205 |
ISTNM1 = ISTNLV - irun |
4206 |
NLEVP1 = NLEV + 1 |
4207 |
ISTNLX = ISTNM1 |
4208 |
IF(ITYPE.EQ.2) ISTNLX = ISTNLV |
4209 |
C |
4210 |
C DEFINE MATRIX |
4211 |
C |
4212 |
DO 10 I=1,irun |
4213 |
CC(I,1) = 0. |
4214 |
10 CONTINUE |
4215 |
DO 20 I=1,ISTNLX |
4216 |
CC(I,2) = RHOKDZ(I,1) * FLXFAC(I,2) |
4217 |
20 CONTINUE |
4218 |
DO 30 I=1,ISTNLV |
4219 |
BB(I,1) = RHOKDZ(I,1) * FLXFAC(I,1) |
4220 |
AA(I,1) = 1. + CC(I,1) + BB(I,1) |
4221 |
30 CONTINUE |
4222 |
C |
4223 |
C ADD IMPLICIT BACKWARD FORCING FOR QQ |
4224 |
IF(ITYPE.EQ.1) THEN |
4225 |
DO 40 I=1,ISTNLV |
4226 |
AA(I,1) = AA(I,1) - XX2(I,1) |
4227 |
40 CONTINUE |
4228 |
ENDIF |
4229 |
C |
4230 |
C SOLVE MATRIX EQUATION FOR XX1 |
4231 |
CALL VTRI0(AA,BB,CC,XX1,XX1,NLEV,irun) |
4232 |
C |
4233 |
IF(ITYPE.EQ.2) THEN |
4234 |
C COMPUTE CHANGE AT SURFACE |
4235 |
C |
4236 |
DO 50 I=1,irun |
4237 |
DXX1G(I) = CC(I,NLEVP1) * ( XX1(I,NLEV)-XX1(I,NLEVP1) ) |
4238 |
50 CONTINUE |
4239 |
C |
4240 |
C SOLVE MATRIX FOR SURFACE PERTURBATION |
4241 |
CALL VTRI1(AA,BB,XX2,NLEV,irun) |
4242 |
DO 60 I=1,irun |
4243 |
DXX2G(I) = CC(I,NLEVP1) * ( XX2(I,NLEV)-XX2(I,NLEVP1) ) |
4244 |
60 CONTINUE |
4245 |
ENDIF |
4246 |
C |
4247 |
C SOLVE MATRIX EQUATION FOR XX2 |
4248 |
C |
4249 |
IF(ITYPE.EQ.3) CALL VTRI2 (AA,BB,CC,XX2,XX2,NLEV,irun) |
4250 |
C |
4251 |
C ELIMINATE UNDERFLOW |
4252 |
IF(ITYPE.EQ.1) THEN |
4253 |
DO 70 I=1,ISTNLV |
4254 |
IF( XX1(I,1).LT.EPSL ) XX1(I,1) = 0. |
4255 |
70 CONTINUE |
4256 |
ENDIF |
4257 |
C |
4258 |
RETURN |
4259 |
END |
4260 |
SUBROUTINE VTRI0 ( A,B,C,F,Y,K,irun) |
4261 |
implicit none |
4262 |
|
4263 |
integer k,irun |
4264 |
_RL A(irun,K),B(irun,K),C(irun,K),Y(irun,K+1) |
4265 |
_RL F(irun,K) |
4266 |
|
4267 |
integer i,L,Lm1 |
4268 |
C |
4269 |
DO 9000 I = 1,irun |
4270 |
A(I,1) = 1. / A(I,1) |
4271 |
9000 CONTINUE |
4272 |
C |
4273 |
DO 100 L = 2,K |
4274 |
LM1 = L - 1 |
4275 |
DO 9002 I = 1,irun |
4276 |
C(I,L) = C(I,L) * A(I,LM1) |
4277 |
A(I,L) = 1. / ( A(I,L) - B(I,LM1) * C(I,L) ) |
4278 |
F(I,L) = F(I,L) + F(I,LM1) * C(I,L) |
4279 |
9002 CONTINUE |
4280 |
100 CONTINUE |
4281 |
C |
4282 |
DO 200 L = K,1,-1 |
4283 |
DO 9004 I = 1,irun |
4284 |
Y(I,L) = (F(I,L) + B(I,L) * Y(I,L+1)) * A(I,L) |
4285 |
9004 CONTINUE |
4286 |
200 CONTINUE |
4287 |
C |
4288 |
RETURN |
4289 |
END |
4290 |
C |
4291 |
SUBROUTINE VTRI1 ( A,B,Y,K,irun) |
4292 |
implicit none |
4293 |
|
4294 |
integer k,irun |
4295 |
_RL A(irun,K),B(irun,K),Y(irun,K+1) |
4296 |
|
4297 |
integer i,L |
4298 |
C |
4299 |
DO 200 L = K,1,-1 |
4300 |
DO 9000 I = 1,irun |
4301 |
Y(I,L) = B(I,L) * Y(I,L+1) * A(I,L) |
4302 |
9000 CONTINUE |
4303 |
200 CONTINUE |
4304 |
C |
4305 |
RETURN |
4306 |
END |
4307 |
C |
4308 |
SUBROUTINE VTRI2 ( A,B,C,F,Y,K,irun) |
4309 |
implicit none |
4310 |
|
4311 |
integer k,irun |
4312 |
_RL A(irun,K),B(irun,K),C(irun,K),F(irun,K) |
4313 |
_RL Y(irun,K+1) |
4314 |
|
4315 |
integer i,L |
4316 |
C |
4317 |
DO 100 L = 2,K |
4318 |
DO 9000 I = 1,irun |
4319 |
F(I,L) = F(I,L) + F(I,L-1) * C(I,L) |
4320 |
9000 CONTINUE |
4321 |
100 CONTINUE |
4322 |
C |
4323 |
DO 200 L = K,1,-1 |
4324 |
DO 9002 I = 1,irun |
4325 |
Y(I,L) = (F(I,L) + B(I,L) * Y(I,L+1)) * A(I,L) |
4326 |
9002 CONTINUE |
4327 |
200 CONTINUE |
4328 |
C |
4329 |
RETURN |
4330 |
END |
4331 |
SUBROUTINE LINADJ ( NN,VRIB1,VRIB2,VWS1,VWS2,VZ1,VUSTAR,IWATER, |
4332 |
1 VAPSIM, VAPSIHG,VPSIH,VPSIG,VX,VX0,VY,VY0,ITYPE,LWATER,IRUN, |
4333 |
2 VDZETA,VDZ0,VDPSIM,VDPSIH,INTRIB, |
4334 |
3 VX0PSIM,VG,VG0,VR1MG0,VZ2,VDZSEA,VAZ0,VXNUM1,VPSIGB2,VDX, |
4335 |
4 VDXPSIM,VDY,VXNUM2,VDEN,VAWS1,VXNUM3,VXNUM,VDZETA1,VDZETA2, |
4336 |
5 VZCOEF2,VZCOEF1,VTEMPLIN,VDPSIMC,VDPSIHC) |
4337 |
C |
4338 |
C********************************************************************** |
4339 |
C |
4340 |
C ARGUMENTS :: |
4341 |
C |
4342 |
C INPUT: |
4343 |
C ------ |
4344 |
C RIB1 - BULK RICHARDSON NUMBER OF INPUT STATE |
4345 |
C RIB2 - DESIRED BULK RICH NUMBER OF OUTPUT STATE |
4346 |
C WS1 - SURFACE WIND SPEED OF INPUT STATE |
4347 |
C WS2 - DESIRED SURFACE WIND SPEED OF OUTPUT STATE |
4348 |
C Z1 - INPUT VALUE OF ROUGHNESS HEIGHT |
4349 |
C USTAR - INPUT VALUE OF CU * WS |
4350 |
C WATER - BIT ARRAY - '1' WHERE OCEAN |
4351 |
C APSIM - (1/PSIM) |
4352 |
C APSIHG - ( 1 / (PSIH+PSIG) ) |
4353 |
C PSIH - NON-DIM TEMP GRADIENT |
4354 |
C PSIG - PSIH FOR THE MOLECULAR LAYER |
4355 |
C X - PHIM(ZETA) - DERIVATIVE OF PSIM |
4356 |
C X0 - PHIM(ZETA0) |
4357 |
C Y - PHIH(ZETA) - DERIVATIVE OF PSIH |
4358 |
C Y0 - PHIH(ZETA0) |
4359 |
C ITYPE - INTEGER FLAG : |
4360 |
C 1 = NEUTRAL ADJUSTMENT |
4361 |
C 2 = ADJ FOR 2ND OR GREATER TRBFLX ITER |
4362 |
C 3 - 5 = ADJUSTMENT INSIDE LOOP |
4363 |
C 4 - 5 = ADJUST CU AND CT |
4364 |
C 5 = PREPARATION FOR ITYPE = 2 |
4365 |
C LWATER - LOGICAL - .TRUE. IF THERE ARE WATER POINTS |
4366 |
C |
4367 |
C OUTPUT: |
4368 |
C ------- |
4369 |
C DZETA - D LOG ZETA |
4370 |
C DZ0 - D Z0 (ITYPE 1) OR D LOG Z0 (ITYPE 2-5) |
4371 |
C DPSIM - D PSIM |
4372 |
C DPSIH - D PSIH |
4373 |
C BITRIB - BIT ARRAY - '1' WHERE RIB1 = 0 |
4374 |
C |
4375 |
C********************************************************************** |
4376 |
implicit none |
4377 |
|
4378 |
C Argument List Declarations |
4379 |
integer nn,irun,itype |
4380 |
_RL VRIB1(IRUN),VRIB2(IRUN) |
4381 |
_RL VWS1(IRUN),VWS2(IRUN),VZ1(IRUN),VUSTAR(IRUN) |
4382 |
integer IWATER(IRUN) |
4383 |
_RL VAPSIM(IRUN),VAPSIHG(IRUN) |
4384 |
_RL VPSIH(IRUN),VPSIG(IRUN),VX(IRUN) |
4385 |
_RL VX0(IRUN),VY(IRUN),VY0(IRUN) |
4386 |
LOGICAL LWATER |
4387 |
_RL VDZETA(IRUN),VDZ0(IRUN),VDPSIM(IRUN) |
4388 |
_RL VDPSIH(IRUN) |
4389 |
integer INTRIB(IRUN) |
4390 |
_RL VX0PSIM(irun),VG(irun),VG0(irun),VR1MG0(irun) |
4391 |
_RL VZ2(irun),VDZSEA(irun),VAZ0(irun),VXNUM1(irun) |
4392 |
_RL VPSIGB2(irun),VDX(irun),VDXPSIM(irun),VDY(irun) |
4393 |
_RL VXNUM2(irun),VDEN(irun),VAWS1(irun),VXNUM3(irun) |
4394 |
_RL VXNUM(irun),VDZETA1(irun),VDZETA2(irun) |
4395 |
_RL VZCOEF2(irun),VZCOEF1(irun),VTEMPLIN(irun) |
4396 |
_RL VDPSIMC(irun),VDPSIHC(irun) |
4397 |
|
4398 |
C Local Variables |
4399 |
_RL xx0max,prfac,xpfac,difsqt,ustz0s,h0byz0,usth0s |
4400 |
PARAMETER ( XX0MAX = 1.49821 ) |
4401 |
PARAMETER ( PRFAC = 0.595864 ) |
4402 |
PARAMETER ( XPFAC = .55 ) |
4403 |
PARAMETER ( DIFSQT = 3.872983E-3) |
4404 |
PARAMETER ( USTZ0S = 0.2030325E-5) |
4405 |
PARAMETER ( H0BYZ0 = 30.0 ) |
4406 |
PARAMETER ( USTH0S = H0BYZ0*USTZ0S ) |
4407 |
|
4408 |
integer VINT1(irun),VINT2(irun) |
4409 |
_RL getcon,vk,bmdl,b2uhs |
4410 |
integer i |
4411 |
C |
4412 |
vk = getcon('VON KARMAN') |
4413 |
BMDL = VK * XPFAC * PRFAC / DIFSQT |
4414 |
B2UHS = BMDL * BMDL * USTH0S |
4415 |
|
4416 |
C COMPUTE X0/PSIM, 1/Z0, G, G0, 1/(1-G0), |
4417 |
C DEL LOG Z0, D LOG ZO / D USTAR |
4418 |
C |
4419 |
CCCOOOMMMM ADDED 'WHERE WATER' |
4420 |
IF ( (ITYPE.EQ.1) .AND. LWATER ) THEN |
4421 |
DO 9000 I = 1,IRUN |
4422 |
IF (IWATER(I).EQ.1) VX0PSIM(I) = VAPSIM(I) |
4423 |
9000 CONTINUE |
4424 |
ENDIF |
4425 |
IF ( ITYPE .GE. 3 ) THEN |
4426 |
DO 9002 I = 1,IRUN |
4427 |
VX0PSIM(I) = VX0(I) * VAPSIM(I) |
4428 |
9002 CONTINUE |
4429 |
ENDIF |
4430 |
IF ( ITYPE .NE. 2 ) THEN |
4431 |
C |
4432 |
DO 9004 I = 1,IRUN |
4433 |
VDZ0(I) = 0. |
4434 |
VG(I) = 0. |
4435 |
VG0(I) = 0. |
4436 |
VR1MG0(I) = 1. |
4437 |
9004 CONTINUE |
4438 |
C |
4439 |
IF ( LWATER ) THEN |
4440 |
CALL ZCSUB ( VUSTAR,VDZSEA,IWATER,.TRUE.,IRUN,VZ2) |
4441 |
C |
4442 |
DO 9006 I = 1,IRUN |
4443 |
IF ( IWATER(I).EQ.1) THEN |
4444 |
VAZ0(I) = 1. / VZ1(I) |
4445 |
VG(I) = VDZSEA(I) * VAZ0(I) |
4446 |
VG0(I) = VX0PSIM(I) * VG(I) |
4447 |
VR1MG0(I) = 1. / ( 1. - VG0(I) ) |
4448 |
VDZ0(I) = ( VZ2(I) - VZ1(I) ) * VR1MG0(I) |
4449 |
ENDIF |
4450 |
9006 CONTINUE |
4451 |
ENDIF |
4452 |
ENDIF |
4453 |
C |
4454 |
IF ( LWATER .AND. (ITYPE.GE.3) ) THEN |
4455 |
DO 9008 I = 1,IRUN |
4456 |
IF (IWATER(I).EQ.1) VDZ0(I) = VDZ0(I) * VAZ0(I) |
4457 |
9008 CONTINUE |
4458 |
ENDIF |
4459 |
C |
4460 |
C COMPUTE NUM1,NUM2,NUM3, DEN |
4461 |
C |
4462 |
IF (ITYPE.GE.3) THEN |
4463 |
DO 9010 I = 1,IRUN |
4464 |
VXNUM1(I) = 0. |
4465 |
IF (VRIB1(I).EQ.0.) THEN |
4466 |
INTRIB(I) = 1 |
4467 |
ELSE |
4468 |
INTRIB(I) = 0 |
4469 |
ENDIF |
4470 |
IF ( INTRIB(I).EQ.0 ) VXNUM1(I) = 1. / VRIB1(I) |
4471 |
VPSIGB2(I) = 0. |
4472 |
if(vpsig(i).gt.0.)VPSIGB2(I) = |
4473 |
1 0.5 * ( vpsig(i)*vpsig(i) + b2uhs ) / vpsig(i) |
4474 |
VDX(I) = VX(I) - VX0(I) |
4475 |
VDXPSIM(I) = VDX(I) * VAPSIM(I) |
4476 |
VDY(I) = VY(I) - VY0(I) |
4477 |
VXNUM3(I) = - VPSIGB2(I) |
4478 |
C |
4479 |
IF ( LWATER ) THEN |
4480 |
CCCOOOMMMM ADDED 'WHERE WATER' |
4481 |
IF (IWATER(I).EQ.1) THEN |
4482 |
VDXPSIM(I) = VDXPSIM(I) * VR1MG0(I) |
4483 |
VXNUM3(I) = VXNUM3(I) + VG(I) * ( VY0(I) - VPSIGB2(I) ) |
4484 |
VXNUM2(I) = VY0(I) - VPSIGB2(I) - VX0PSIM(I) * VPSIGB2(I) |
4485 |
VXNUM2(I) = (VXNUM2(I) * VAPSIHG(I)) - 2. * VX0PSIM(I) |
4486 |
VXNUM2(I) = VXNUM2(I) * VDZ0(I) |
4487 |
ENDIF |
4488 |
ENDIF |
4489 |
C |
4490 |
VDEN(I) = VDY(I) + VDXPSIM(I) * VXNUM3(I) |
4491 |
VDEN(I) = ( 1. + VDEN(I) * VAPSIHG(I) ) - 2. * VDXPSIM(I) |
4492 |
9010 CONTINUE |
4493 |
ENDIF |
4494 |
C |
4495 |
IF (ITYPE.EQ.5) THEN |
4496 |
DO 9012 I = 1,IRUN |
4497 |
VAWS1(I) = VR1MG0(I) / VWS1(I) |
4498 |
VXNUM3(I) = VXNUM3(I) * VAPSIHG(I) |
4499 |
C |
4500 |
IF ( LWATER ) THEN |
4501 |
CCCOOOMMMM ADDED 'WHERE WATER' |
4502 |
IF(IWATER(I).EQ.1) THEN |
4503 |
VXNUM3(I) = VXNUM3(I) - 2. * VG0(I) |
4504 |
VXNUM3(I) = VAWS1(I) * VXNUM3(I) |
4505 |
ENDIF |
4506 |
ENDIF |
4507 |
9012 CONTINUE |
4508 |
ENDIF |
4509 |
C |
4510 |
C COMPUTE D LOG ZETA |
4511 |
C |
4512 |
IF (ITYPE.GE.2) THEN |
4513 |
DO 9014 I = 1,IRUN |
4514 |
VXNUM(I) = VRIB2(I) - VRIB1(I) |
4515 |
IF( (VX0(I).GT.XX0MAX).AND.(VXNUM(I).GE.0.) )VXNUM(I) = 0. |
4516 |
VXNUM(I) = VXNUM1(I) * VXNUM(I) |
4517 |
9014 CONTINUE |
4518 |
ENDIF |
4519 |
C |
4520 |
IF ( ITYPE.EQ.2 )THEN |
4521 |
DO 9016 I = 1,IRUN |
4522 |
VDZETA1(I) = VDZETA(I) |
4523 |
VXNUM(I) = VXNUM(I) + VXNUM3(I) * ( VWS2(I) - VWS1(I) ) |
4524 |
9016 CONTINUE |
4525 |
ENDIF |
4526 |
C |
4527 |
IF (ITYPE.GE.3) THEN |
4528 |
DO 9018 I = 1,IRUN |
4529 |
VDZETA1(I) = VXNUM(I) |
4530 |
IF(LWATER.AND.(IWATER(I).EQ.1)) VXNUM(I) = VXNUM(I) + VXNUM2(I) |
4531 |
IF ( VDEN(I) .LT.0.1 ) VDEN(I) = 0.1 |
4532 |
9018 CONTINUE |
4533 |
ENDIF |
4534 |
C |
4535 |
IF (ITYPE.GE.2) THEN |
4536 |
DO 9020 I = 1,IRUN |
4537 |
VDZETA(I) = VXNUM(I) / VDEN(I) |
4538 |
9020 CONTINUE |
4539 |
ENDIF |
4540 |
IF (ITYPE.GE.3) THEN |
4541 |
DO 9022 I = 1,IRUN |
4542 |
IF ( (VRIB2(I).EQ.0.) .OR. (VDZETA(I).LE.-1.) ) THEN |
4543 |
VINT1(I) = 1 |
4544 |
ELSE |
4545 |
VINT1(I) = 0 |
4546 |
ENDIF |
4547 |
IF ( VINT1(I).EQ.1 ) VDZETA(I) = VDZETA1(I) |
4548 |
9022 CONTINUE |
4549 |
ENDIF |
4550 |
IF (ITYPE.EQ.2) THEN |
4551 |
DO 9024 I = 1,IRUN |
4552 |
VDZETA2(I) = VDZETA(I) + VDZETA1(I) |
4553 |
IF ( (VRIB2(I).EQ.0.) .OR. (VDZETA2(I).LE.-1.) ) THEN |
4554 |
VINT1(I) = 1 |
4555 |
ELSE |
4556 |
VINT1(I) = 0 |
4557 |
ENDIF |
4558 |
IF(VINT1(I).EQ.1)VDZETA(I)=VXNUM1(I)*VRIB2(I) - 1. - VDZETA1(I) |
4559 |
9024 CONTINUE |
4560 |
ENDIF |
4561 |
|
4562 |
C |
4563 |
C COMPUTE D LOG Z0 |
4564 |
C |
4565 |
IF ( LWATER .AND. (ITYPE.GE.3) )THEN |
4566 |
DO 9026 I = 1,IRUN |
4567 |
IF( IWATER(I).EQ.1 ) THEN |
4568 |
VZCOEF2(I) = VG(I) * VDXPSIM(I) |
4569 |
VDZ0(I) = VDZ0(I) - VZCOEF2(I) * VDZETA(I) |
4570 |
ENDIF |
4571 |
9026 CONTINUE |
4572 |
ENDIF |
4573 |
C |
4574 |
IF ( LWATER .AND. (ITYPE.EQ.5) ) THEN |
4575 |
DO 9028 I = 1,IRUN |
4576 |
IF(IWATER(I).EQ.1) VZCOEF1(I) = VG(I) * VAWS1(I) |
4577 |
9028 CONTINUE |
4578 |
ENDIF |
4579 |
C |
4580 |
IF ( LWATER .AND. (ITYPE.EQ.2) ) THEN |
4581 |
DO 9030 I = 1,IRUN |
4582 |
IF (IWATER(I).EQ.1) VDZ0(I) = |
4583 |
1 VZCOEF1(I) * ( VWS2(I) - VWS1(I) ) - VZCOEF2(I) * VDZETA(I) |
4584 |
9030 CONTINUE |
4585 |
ENDIF |
4586 |
C |
4587 |
C CALCULATE D PSIM AND D PSIH |
4588 |
C |
4589 |
IF ( (ITYPE.EQ.1) .AND. LWATER ) THEN |
4590 |
DO 9032 I = 1,IRUN |
4591 |
IF (IWATER(I).EQ.1) THEN |
4592 |
VDPSIM(I) = - VDZ0(I) * VAZ0(I) |
4593 |
VDPSIH(I) = VDPSIM(I) |
4594 |
ENDIF |
4595 |
9032 CONTINUE |
4596 |
ENDIF |
4597 |
C |
4598 |
IF (ITYPE.GE.3) THEN |
4599 |
DO 9034 I = 1,IRUN |
4600 |
VDPSIM(I) = VDX(I) * VDZETA(I) |
4601 |
VDPSIH(I) = VDY(I) * VDZETA(I) |
4602 |
IF ( LWATER ) THEN |
4603 |
IF (IWATER(I).EQ.1 ) THEN |
4604 |
VDPSIM(I) = VDPSIM(I) - VX0(I) * VDZ0(I) |
4605 |
VDPSIH(I) = VDPSIH(I) - VY0(I) * VDZ0(I) |
4606 |
ENDIF |
4607 |
ENDIF |
4608 |
9034 CONTINUE |
4609 |
ENDIF |
4610 |
C |
4611 |
C PREVENT OVERCORRECTION OF PSIM OR PSIH FOR UNSTABLE CASE |
4612 |
C |
4613 |
IF (ITYPE.GE.4) THEN |
4614 |
DO 9036 I = 1,IRUN |
4615 |
VDPSIMC(I) = -0.9 - VDPSIM(I) * VAPSIM(I) |
4616 |
VDPSIHC(I) = -0.9 * VPSIH(I) - VDPSIH(I) |
4617 |
IF ( VDPSIMC(I).GT.0. ) THEN |
4618 |
VINT1(I) = 1 |
4619 |
ELSE |
4620 |
VINT1(I) = 0 |
4621 |
ENDIF |
4622 |
IF ( VDPSIHC(I).GT.0. ) THEN |
4623 |
VINT2(I) = 1 |
4624 |
ELSE |
4625 |
VINT2(I) = 0 |
4626 |
ENDIF |
4627 |
VDZETA1(I) = 0. |
4628 |
IF(VINT1(I).EQ.1) VDZETA1(I) = VDPSIMC(I) / VDXPSIM(I) |
4629 |
IF((VINT1(I).EQ.1).OR.(VINT2(I).EQ.1)) VTEMPLIN(I) = |
4630 |
1 VDY(I) + VY0(I) * VG(I) * VDXPSIM(I) |
4631 |
IF (VINT2(I).EQ.1) then |
4632 |
VDZETA2(I) = VDPSIHC(I) / VTEMPLIN(I) |
4633 |
IF ( VDZETA2(I).LT.VDZETA1(I) ) VDZETA1(I) = VDZETA2(I) |
4634 |
endif |
4635 |
IF((VINT1(I).EQ.1).OR.(VINT2(I).EQ.1)) THEN |
4636 |
VDZETA(I) = VDZETA1(I) + VDZETA(I) |
4637 |
VDPSIM(I) = VDPSIM(I) + VDX(I) * VR1MG0(I) * VDZETA1(I) |
4638 |
VDPSIH(I) = VDPSIH(I) + VTEMPLIN(I) * VDZETA1(I) |
4639 |
IF ( IWATER(I).EQ.1 ) |
4640 |
1 VDZ0(I) = VDZ0(I) - VG(I) * VDXPSIM(I) * VDZETA1(I) |
4641 |
ENDIF |
4642 |
9036 CONTINUE |
4643 |
ENDIF |
4644 |
C |
4645 |
RETURN |
4646 |
END |
4647 |
SUBROUTINE ZCSUB (VUSTAR,VDZSEA,IWATER,LDZSEA,IRUN,VZSEA) |
4648 |
C********************************************************************** |
4649 |
C FUNCTION ZSEA |
4650 |
C PURPOSE |
4651 |
C COMPUTES Z0 AS A FUNCTION OF USTAR OVER WATER SURFACES |
4652 |
C USAGE |
4653 |
C CALLED BY SFCFLX |
4654 |
C DESCRIPTION OF PARAMETERS |
4655 |
C USTAR - INPUTED VALUE OF SURFACE-STRESS VELOCITY |
4656 |
C DZSEA - OUTPUTED VALUE OF DERIVATIVE D(ZSEA)/D(USTAR) |
4657 |
C WATER - INPUTED BIT VECTOR TO DETERMINE WATER POINTS |
4658 |
C LDZSEA- LOGICAL FLAG TO DETERMINE IF DZSEA SHOULD BE COMPUTED |
4659 |
C ZSEA - OUTPUTED VALUE OF ROUGHNESS LENGTH |
4660 |
C SUBPROGRAMS NEEDED |
4661 |
C NONE |
4662 |
C RECORD OF MODIFICATIONS |
4663 |
C REMARKS: |
4664 |
C COMPUTE ROUGHNESS LENGTH FOR OCEAN POINTS |
4665 |
C BASED ON FUNCTIONS OF LARGE AND POND |
4666 |
C AND OF KONDO --- DESIGNED FOR K = .4 |
4667 |
C ********************************************************************* |
4668 |
implicit none |
4669 |
|
4670 |
C Argument List Delcarations |
4671 |
integer irun |
4672 |
_RL VZSEA(IRUN),VUSTAR(IRUN),VDZSEA(IRUN) |
4673 |
integer IWATER(IRUN) |
4674 |
LOGICAL LDZSEA |
4675 |
|
4676 |
C Local Variables |
4677 |
_RL USTMX1,USTMX2,USTMX3 |
4678 |
PARAMETER ( USTMX1 = 1.14973 ) |
4679 |
PARAMETER ( USTMX2 = 0.381844 ) |
4680 |
PARAMETER ( USTMX3 = 0.0632456) |
4681 |
|
4682 |
_RL AA(IRUN,5),TEMP(IRUN) |
4683 |
integer INT2(IRUN),INT3(IRUN),INT4(IRUN) |
4684 |
integer i,k |
4685 |
|
4686 |
_RL AA1(5),AA2(5),AA3(5),AA4(5) |
4687 |
DATA AA1/.2030325E-5,0.0,0.0,0.0,0.0/ |
4688 |
DATA AA2/-0.402451E-08,0.239597E-04,0.117484E-03,0.191918E-03, |
4689 |
1 0.395649E-04/ |
4690 |
DATA AA3/-0.237910E-04,0.228221E-03,-0.860810E-03,0.176543E-02, |
4691 |
1 0.784260E-04/ |
4692 |
DATA AA4/-0.343228E-04,0.552305E-03,-0.167541E-02,0.250208E-02, |
4693 |
1 -0.153259E-03/ |
4694 |
C |
4695 |
C********************************************************************** |
4696 |
C***** LOWER CUTOFF CONDITION FOR USTAR *** |
4697 |
C********************************************************************** |
4698 |
C |
4699 |
DO 9000 I = 1,IRUN |
4700 |
IF(VUSTAR(I) .LT. 1.e-6)THEN |
4701 |
INT3(I) = 1 |
4702 |
ELSE |
4703 |
INT3(I) = 0 |
4704 |
ENDIF |
4705 |
9000 CONTINUE |
4706 |
DO 9002 I = 1,IRUN |
4707 |
IF(INT3(I).EQ.1) VUSTAR(I) = 1.e-6 |
4708 |
9002 CONTINUE |
4709 |
C |
4710 |
C*********************************** |
4711 |
C***** LOAD THE ARRAY A(I,K) ***** |
4712 |
C*********************************** |
4713 |
C |
4714 |
DO 9004 I = 1,IRUN |
4715 |
IF( (VUSTAR(I) .GT. USTMX1) .AND. (IWATER(I).EQ.1) ) THEN |
4716 |
INT4(I) = 1 |
4717 |
ELSE |
4718 |
INT4(I) = 0 |
4719 |
ENDIF |
4720 |
9004 CONTINUE |
4721 |
DO 9006 I = 1,IRUN |
4722 |
IF(VUSTAR(I) .GT. USTMX2) THEN |
4723 |
INT3(I) = 1 |
4724 |
ELSE |
4725 |
INT3(I) = 0 |
4726 |
ENDIF |
4727 |
9006 CONTINUE |
4728 |
DO 9008 I = 1,IRUN |
4729 |
IF(VUSTAR(I) .GE. USTMX3) THEN |
4730 |
INT2(I) = 1 |
4731 |
ELSE |
4732 |
INT2(I) = 0 |
4733 |
ENDIF |
4734 |
9008 CONTINUE |
4735 |
C |
4736 |
DO 100 K=1,5 |
4737 |
DO 9010 I = 1,IRUN |
4738 |
AA(I,K) = AA1(K) |
4739 |
IF( INT2(I).EQ.1 ) AA(I,K) = AA2(K) |
4740 |
IF( INT3(I).EQ.1 ) AA(I,K) = AA3(K) |
4741 |
IF( INT4(I).EQ.1 ) AA(I,K) = AA4(K) |
4742 |
9010 CONTINUE |
4743 |
100 CONTINUE |
4744 |
C |
4745 |
C******************************************************** |
4746 |
C***** EVALUATE THE ENHANCED POLYNOMIAL FOR ZSEA ***** |
4747 |
C******************************************************** |
4748 |
C |
4749 |
DO 9012 I = 1,IRUN |
4750 |
VDZSEA(I) = ( AA(I,4) + AA(I,5) * VUSTAR(I) ) * VUSTAR(I) |
4751 |
VZSEA(I) = AA(I,2) + ( AA(I,3) + VDZSEA(I) ) * VUSTAR(I) |
4752 |
TEMP(I) = AA(I,1) / VUSTAR(I) |
4753 |
VZSEA(I) = VZSEA(I) + TEMP(I) |
4754 |
9012 CONTINUE |
4755 |
C |
4756 |
C********************************************************************** |
4757 |
C***** EVALUATE THE DERIVATIVE DZSEA IF LDZSEA IS TRUE *** |
4758 |
C********************************************************************** |
4759 |
C |
4760 |
IF( LDZSEA ) THEN |
4761 |
DO 9014 I = 1,IRUN |
4762 |
VDZSEA(I) = 3. * VDZSEA(I) -(AA(I,4)*VUSTAR(I) - AA(I,3)) |
4763 |
VDZSEA(I) = VDZSEA(I) * VUSTAR(I) - TEMP(I) |
4764 |
9014 CONTINUE |
4765 |
ENDIF |
4766 |
C |
4767 |
RETURN |
4768 |
END |
4769 |
|
4770 |
subroutine seaice ( nocean, timstp, hice, |
4771 |
. eturb, dedtc, |
4772 |
. hsturb, dhsdtc, |
4773 |
. qice, dqice, |
4774 |
. swnet, lwnet, dst4, |
4775 |
. pke, seaic, tc, qa ) |
4776 |
implicit none |
4777 |
integer nocean |
4778 |
_RL timstp |
4779 |
_RL eturb(nocean),dedtc(nocean),hsturb(nocean),dhsdtc(nocean) |
4780 |
_RL swnet(nocean),lwnet(nocean), dst4(nocean) |
4781 |
_RL qice(nocean),dqice(nocean) |
4782 |
_RL pke(nocean), tc(nocean), qa(nocean) |
4783 |
_RL seaic(nocean) |
4784 |
|
4785 |
C rho*C = 1.93e6 J/(m**3 K) ; Peixoto & Oort |
4786 |
_RL rhoC |
4787 |
parameter (rhoC = 1.93e6) |
4788 |
|
4789 |
_RL faceps,getcon,latent,codt,deltg,hice |
4790 |
integer i |
4791 |
|
4792 |
faceps = getcon('EPSFAC') |
4793 |
latent = getcon('HEATI') * getcon('CALTOJ') |
4794 |
C Note hice is in centimeters |
4795 |
codt = rhoC * (hice/100) / timstp |
4796 |
|
4797 |
c Update TC and QA |
4798 |
c ---------------- |
4799 |
do i =1,nocean |
4800 |
if( seaic(i).gt.0.0 ) then |
4801 |
deltg = ( swnet(i)-lwnet(i)-latent*eturb(i)-hsturb(i)+qice(i) ) |
4802 |
. / ( codt+dst4(i)+latent*dedtc(i)+dhsdtc(i)-dqice(i) ) |
4803 |
qa(i) = qa(i) + (faceps*qa(i)/(tc(i)*tc(i)))*deltg |
4804 |
tc(i) = tc(i) + deltg |
4805 |
endif |
4806 |
enddo |
4807 |
|
4808 |
return |
4809 |
end |