1 |
module cv30_yield_m |
2 |
|
3 |
implicit none |
4 |
|
5 |
contains |
6 |
|
7 |
SUBROUTINE cv30_yield(nloc, ncum, nd, na, icb, inb, delt, t, rr, u, v, gz, & |
8 |
p, ph, h, hp, lv, cpn, th, ep, clw, m, tp, mp, rp, up, vp, wt, water, & |
9 |
evap, b, ment, qent, uent, vent, nent, elij, sig, tv, tvp, iflag, & |
10 |
precip, VPrecip, ft, fr, fu, fv, upwd, dnwd, dnwd0, ma, mike, tls, & |
11 |
tps, qcondc, wd) |
12 |
|
13 |
use conema3_m, only: iflag_clw |
14 |
use cv30_param_m, only: delta, minorig, nl, sigd |
15 |
use cvthermo, only: cl, cpd, cpv, grav, rowl, rrd, rrv |
16 |
|
17 |
! inputs: |
18 |
integer, intent(in):: ncum, nd, na, nloc |
19 |
integer, intent(in):: icb(nloc), inb(nloc) |
20 |
real, intent(in):: delt |
21 |
real t(nloc, nd), rr(nloc, nd), u(nloc, nd), v(nloc, nd) |
22 |
real sig(nloc, nd) |
23 |
real gz(nloc, na), ph(nloc, nd+1), h(nloc, na), hp(nloc, na) |
24 |
real th(nloc, na), p(nloc, nd), tp(nloc, na) |
25 |
real lv(nloc, na), cpn(nloc, na), ep(nloc, na), clw(nloc, na) |
26 |
real m(nloc, na), mp(nloc, na), rp(nloc, na), up(nloc, na) |
27 |
real vp(nloc, na), wt(nloc, nd) |
28 |
real water(nloc, na), evap(nloc, na), b(nloc, na) |
29 |
real ment(nloc, na, na), qent(nloc, na, na), uent(nloc, na, na) |
30 |
!ym real vent(nloc, na, na), nent(nloc, na), elij(nloc, na, na) |
31 |
real vent(nloc, na, na), elij(nloc, na, na) |
32 |
integer nent(nloc, na) |
33 |
real tv(nloc, nd), tvp(nloc, nd) |
34 |
|
35 |
! input/output: |
36 |
integer iflag(nloc) |
37 |
|
38 |
! outputs: |
39 |
real precip(nloc) |
40 |
real VPrecip(nloc, nd+1) |
41 |
real ft(nloc, nd), fr(nloc, nd), fu(nloc, nd), fv(nloc, nd) |
42 |
real upwd(nloc, nd), dnwd(nloc, nd), ma(nloc, nd) |
43 |
real dnwd0(nloc, nd), mike(nloc, nd) |
44 |
real tls(nloc, nd), tps(nloc, nd) |
45 |
real qcondc(nloc, nd) ! cld |
46 |
real wd(nloc) ! gust |
47 |
|
48 |
! local variables: |
49 |
integer i, k, il, n, j, num1 |
50 |
real rat, awat, delti |
51 |
real ax, bx, cx, dx |
52 |
real cpinv, rdcp, dpinv |
53 |
real lvcp(nloc, na) |
54 |
real am(nloc), work(nloc), ad(nloc), amp1(nloc) |
55 |
!!! real up1(nloc), dn1(nloc) |
56 |
real up1(nloc, nd, nd), dn1(nloc, nd, nd) |
57 |
real asum(nloc), bsum(nloc), csum(nloc), dsum(nloc) |
58 |
real qcond(nloc, nd), nqcond(nloc, nd), wa(nloc, nd) ! cld |
59 |
real siga(nloc, nd), sax(nloc, nd), mac(nloc, nd) ! cld |
60 |
|
61 |
!------------------------------------------------------------- |
62 |
|
63 |
! initialization: |
64 |
|
65 |
delti = 1.0/delt |
66 |
|
67 |
do il=1, ncum |
68 |
precip(il)=0.0 |
69 |
wd(il)=0.0 ! gust |
70 |
VPrecip(il, nd+1)=0. |
71 |
enddo |
72 |
|
73 |
do i=1, nd |
74 |
do il=1, ncum |
75 |
VPrecip(il, i)=0.0 |
76 |
ft(il, i)=0.0 |
77 |
fr(il, i)=0.0 |
78 |
fu(il, i)=0.0 |
79 |
fv(il, i)=0.0 |
80 |
qcondc(il, i)=0.0 ! cld |
81 |
qcond(il, i)=0.0 ! cld |
82 |
nqcond(il, i)=0.0 ! cld |
83 |
enddo |
84 |
enddo |
85 |
|
86 |
do i=1, nl |
87 |
do il=1, ncum |
88 |
lvcp(il, i)=lv(il, i)/cpn(il, i) |
89 |
enddo |
90 |
enddo |
91 |
|
92 |
! *** calculate surface precipitation in mm/day *** |
93 |
|
94 |
do il=1, ncum |
95 |
if(ep(il, inb(il)) >= 0.0001)then |
96 |
precip(il)=wt(il, 1)*sigd*water(il, 1)*86400.*1000./(rowl*grav) |
97 |
endif |
98 |
enddo |
99 |
|
100 |
! *** CALCULATE VERTICAL PROFILE OF PRECIPITATIONs IN kg/m2/s === |
101 |
|
102 |
! MAF rajout pour lessivage |
103 |
do k=1, nl |
104 |
do il=1, ncum |
105 |
if (k <= inb(il)) then |
106 |
VPrecip(il, k) = wt(il, k)*sigd*water(il, k)/grav |
107 |
endif |
108 |
end do |
109 |
end do |
110 |
|
111 |
! *** calculate tendencies of lowest level potential temperature *** |
112 |
! *** and mixing ratio *** |
113 |
|
114 |
do il=1, ncum |
115 |
work(il)=1.0/(ph(il, 1)-ph(il, 2)) |
116 |
am(il)=0.0 |
117 |
enddo |
118 |
|
119 |
do k=2, nl |
120 |
do il=1, ncum |
121 |
if (k <= inb(il)) then |
122 |
am(il)=am(il)+m(il, k) |
123 |
endif |
124 |
enddo |
125 |
enddo |
126 |
|
127 |
do il=1, ncum |
128 |
|
129 |
! convect3 if((0.1*dpinv*am) >= delti)iflag(il)=4 |
130 |
if((0.01*grav*work(il)*am(il)) >= delti)iflag(il)=1!consist vect |
131 |
ft(il, 1)=0.01*grav*work(il)*am(il)*(t(il, 2)-t(il, 1) & |
132 |
+(gz(il, 2)-gz(il, 1))/cpn(il, 1)) |
133 |
|
134 |
ft(il, 1)=ft(il, 1)-0.5*lvcp(il, 1)*sigd*(evap(il, 1)+evap(il, 2)) |
135 |
|
136 |
ft(il, 1)=ft(il, 1)-0.009*grav*sigd*mp(il, 2) & |
137 |
*t(il, 1)*b(il, 1)*work(il) |
138 |
|
139 |
ft(il, 1)=ft(il, 1)+0.01*sigd*wt(il, 1)*(cl-cpd)*water(il, 2)*(t(il, 2) & |
140 |
-t(il, 1))*work(il)/cpn(il, 1) |
141 |
|
142 |
!jyg1 Correction pour mieux conserver l'eau (conformite avec CONVECT4.3) |
143 |
! (sb: pour l'instant, on ne fait que le chgt concernant grav, pas evap) |
144 |
fr(il, 1)=0.01*grav*mp(il, 2)*(rp(il, 2)-rr(il, 1))*work(il) & |
145 |
+sigd*0.5*(evap(il, 1)+evap(il, 2)) |
146 |
!+tard : +sigd*evap(il, 1) |
147 |
|
148 |
fr(il, 1)=fr(il, 1)+0.01*grav*am(il)*(rr(il, 2)-rr(il, 1))*work(il) |
149 |
|
150 |
fu(il, 1)=fu(il, 1)+0.01*grav*work(il)*(mp(il, 2)*(up(il, 2)-u(il, 1)) & |
151 |
+am(il)*(u(il, 2)-u(il, 1))) |
152 |
fv(il, 1)=fv(il, 1)+0.01*grav*work(il)*(mp(il, 2)*(vp(il, 2)-v(il, 1)) & |
153 |
+am(il)*(v(il, 2)-v(il, 1))) |
154 |
enddo ! il |
155 |
|
156 |
do j=2, nl |
157 |
do il=1, ncum |
158 |
if (j <= inb(il)) then |
159 |
fr(il, 1)=fr(il, 1) & |
160 |
+0.01*grav*work(il)*ment(il, j, 1)*(qent(il, j, 1)-rr(il, 1)) |
161 |
fu(il, 1)=fu(il, 1) & |
162 |
+0.01*grav*work(il)*ment(il, j, 1)*(uent(il, j, 1)-u(il, 1)) |
163 |
fv(il, 1)=fv(il, 1) & |
164 |
+0.01*grav*work(il)*ment(il, j, 1)*(vent(il, j, 1)-v(il, 1)) |
165 |
endif ! j |
166 |
enddo |
167 |
enddo |
168 |
|
169 |
! *** calculate tendencies of potential temperature and mixing ratio *** |
170 |
! *** at levels above the lowest level *** |
171 |
|
172 |
! *** first find the net saturated updraft and downdraft mass fluxes *** |
173 |
! *** through each level *** |
174 |
|
175 |
do i=2, nl+1 ! newvecto: mettre nl au lieu nl+1? |
176 |
|
177 |
num1=0 |
178 |
do il=1, ncum |
179 |
if(i <= inb(il))num1=num1+1 |
180 |
enddo |
181 |
if(num1 <= 0) cycle |
182 |
|
183 |
amp1(:ncum) = 0. |
184 |
ad(:ncum) = 0. |
185 |
|
186 |
do k=i+1, nl+1 |
187 |
do il=1, ncum |
188 |
if (i <= inb(il) .and. k <= (inb(il)+1)) then |
189 |
amp1(il)=amp1(il)+m(il, k) |
190 |
endif |
191 |
end do |
192 |
end do |
193 |
|
194 |
do k=1, i |
195 |
do j=i+1, nl+1 |
196 |
do il=1, ncum |
197 |
if (i <= inb(il) .and. j <= (inb(il)+1)) then |
198 |
amp1(il)=amp1(il)+ment(il, k, j) |
199 |
endif |
200 |
end do |
201 |
end do |
202 |
end do |
203 |
|
204 |
do k=1, i-1 |
205 |
do j=i, nl+1 ! newvecto: nl au lieu nl+1? |
206 |
do il=1, ncum |
207 |
if (i <= inb(il) .and. j <= inb(il)) then |
208 |
ad(il)=ad(il)+ment(il, j, k) |
209 |
endif |
210 |
end do |
211 |
end do |
212 |
end do |
213 |
|
214 |
do il=1, ncum |
215 |
if (i <= inb(il)) then |
216 |
dpinv=1.0/(ph(il, i)-ph(il, i+1)) |
217 |
cpinv=1.0/cpn(il, i) |
218 |
|
219 |
if((0.01*grav*dpinv*amp1(il)) >= delti)iflag(il)=1 ! vecto |
220 |
|
221 |
ft(il, i)=0.01*grav*dpinv*(amp1(il)*(t(il, i+1)-t(il, i) & |
222 |
+(gz(il, i+1)-gz(il, i))*cpinv) & |
223 |
-ad(il)*(t(il, i)-t(il, i-1)+(gz(il, i)-gz(il, i-1))*cpinv)) & |
224 |
-0.5*sigd*lvcp(il, i)*(evap(il, i)+evap(il, i+1)) |
225 |
rat=cpn(il, i-1)*cpinv |
226 |
ft(il, i)=ft(il, i)-0.009*grav*sigd*(mp(il, i+1)*t(il, i)*b(il, i) & |
227 |
-mp(il, i)*t(il, i-1)*rat*b(il, i-1))*dpinv |
228 |
ft(il, i)=ft(il, i)+0.01*grav*dpinv*ment(il, i, i)*(hp(il, i)-h(il, i) & |
229 |
+t(il, i)*(cpv-cpd)*(rr(il, i)-qent(il, i, i)))*cpinv |
230 |
|
231 |
ft(il, i)=ft(il, i)+0.01*sigd*wt(il, i)*(cl-cpd)*water(il, i+1) & |
232 |
*(t(il, i+1)-t(il, i))*dpinv*cpinv |
233 |
|
234 |
fr(il, i)=0.01*grav*dpinv*(amp1(il)*(rr(il, i+1)-rr(il, i)) & |
235 |
-ad(il)*(rr(il, i)-rr(il, i-1))) |
236 |
fu(il, i)=fu(il, i)+0.01*grav*dpinv*(amp1(il)*(u(il, i+1)-u(il, i)) & |
237 |
-ad(il)*(u(il, i)-u(il, i-1))) |
238 |
fv(il, i)=fv(il, i)+0.01*grav*dpinv*(amp1(il)*(v(il, i+1)-v(il, i)) & |
239 |
-ad(il)*(v(il, i)-v(il, i-1))) |
240 |
endif ! i |
241 |
end do |
242 |
|
243 |
do k=1, i-1 |
244 |
do il=1, ncum |
245 |
if (i <= inb(il)) then |
246 |
dpinv=1.0/(ph(il, i)-ph(il, i+1)) |
247 |
cpinv=1.0/cpn(il, i) |
248 |
|
249 |
awat=elij(il, k, i)-(1.-ep(il, i))*clw(il, i) |
250 |
awat=amax1(awat, 0.0) |
251 |
|
252 |
fr(il, i)=fr(il, i) & |
253 |
+0.01*grav*dpinv*ment(il, k, i)*(qent(il, k, i)-awat-rr(il, i)) |
254 |
fu(il, i)=fu(il, i) & |
255 |
+0.01*grav*dpinv*ment(il, k, i)*(uent(il, k, i)-u(il, i)) |
256 |
fv(il, i)=fv(il, i) & |
257 |
+0.01*grav*dpinv*ment(il, k, i)*(vent(il, k, i)-v(il, i)) |
258 |
|
259 |
! (saturated updrafts resulting from mixing) ! cld |
260 |
qcond(il, i)=qcond(il, i)+(elij(il, k, i)-awat) ! cld |
261 |
nqcond(il, i)=nqcond(il, i)+1. ! cld |
262 |
endif ! i |
263 |
end do |
264 |
end do |
265 |
|
266 |
do k=i, nl+1 |
267 |
do il=1, ncum |
268 |
if (i <= inb(il) .and. k <= inb(il)) then |
269 |
dpinv=1.0/(ph(il, i)-ph(il, i+1)) |
270 |
cpinv=1.0/cpn(il, i) |
271 |
|
272 |
fr(il, i)=fr(il, i) & |
273 |
+0.01*grav*dpinv*ment(il, k, i)*(qent(il, k, i)-rr(il, i)) |
274 |
fu(il, i)=fu(il, i) & |
275 |
+0.01*grav*dpinv*ment(il, k, i)*(uent(il, k, i)-u(il, i)) |
276 |
fv(il, i)=fv(il, i) & |
277 |
+0.01*grav*dpinv*ment(il, k, i)*(vent(il, k, i)-v(il, i)) |
278 |
endif ! i and k |
279 |
end do |
280 |
end do |
281 |
|
282 |
do il=1, ncum |
283 |
if (i <= inb(il)) then |
284 |
dpinv=1.0/(ph(il, i)-ph(il, i+1)) |
285 |
cpinv=1.0/cpn(il, i) |
286 |
|
287 |
! sb: on ne fait pas encore la correction permettant de mieux |
288 |
! conserver l'eau: |
289 |
fr(il, i)=fr(il, i)+0.5*sigd*(evap(il, i)+evap(il, i+1)) & |
290 |
+0.01*grav*(mp(il, i+1)*(rp(il, i+1)-rr(il, i))-mp(il, i) & |
291 |
*(rp(il, i)-rr(il, i-1)))*dpinv |
292 |
|
293 |
fu(il, i)=fu(il, i)+0.01*grav*(mp(il, i+1)*(up(il, i+1)-u(il, i)) & |
294 |
-mp(il, i)*(up(il, i)-u(il, i-1)))*dpinv |
295 |
fv(il, i)=fv(il, i)+0.01*grav*(mp(il, i+1)*(vp(il, i+1)-v(il, i)) & |
296 |
-mp(il, i)*(vp(il, i)-v(il, i-1)))*dpinv |
297 |
|
298 |
endif ! i |
299 |
end do |
300 |
|
301 |
! sb: interface with the cloud parameterization: ! cld |
302 |
|
303 |
do k=i+1, nl |
304 |
do il=1, ncum |
305 |
if (k <= inb(il) .and. i <= inb(il)) then ! cld |
306 |
! (saturated downdrafts resulting from mixing) ! cld |
307 |
qcond(il, i)=qcond(il, i)+elij(il, k, i) ! cld |
308 |
nqcond(il, i)=nqcond(il, i)+1. ! cld |
309 |
endif ! cld |
310 |
enddo ! cld |
311 |
enddo ! cld |
312 |
|
313 |
! (particular case: no detraining level is found) ! cld |
314 |
do il=1, ncum ! cld |
315 |
if (i <= inb(il) .and. nent(il, i) == 0) then ! cld |
316 |
qcond(il, i)=qcond(il, i)+(1.-ep(il, i))*clw(il, i) ! cld |
317 |
nqcond(il, i)=nqcond(il, i)+1. ! cld |
318 |
endif ! cld |
319 |
enddo ! cld |
320 |
|
321 |
do il=1, ncum ! cld |
322 |
if (i <= inb(il) .and. nqcond(il, i) /= 0.) then ! cld |
323 |
qcond(il, i)=qcond(il, i)/nqcond(il, i) ! cld |
324 |
endif ! cld |
325 |
enddo |
326 |
|
327 |
end do |
328 |
|
329 |
! *** move the detrainment at level inb down to level inb-1 *** |
330 |
! *** in such a way as to preserve the vertically *** |
331 |
! *** integrated enthalpy and water tendencies *** |
332 |
|
333 |
do il=1, ncum |
334 |
|
335 |
ax=0.1*ment(il, inb(il), inb(il))*(hp(il, inb(il))-h(il, inb(il)) & |
336 |
+t(il, inb(il))*(cpv-cpd) & |
337 |
*(rr(il, inb(il))-qent(il, inb(il), inb(il)))) & |
338 |
/(cpn(il, inb(il))*(ph(il, inb(il))-ph(il, inb(il)+1))) |
339 |
ft(il, inb(il))=ft(il, inb(il))-ax |
340 |
ft(il, inb(il)-1)=ft(il, inb(il)-1)+ax*cpn(il, inb(il)) & |
341 |
*(ph(il, inb(il))-ph(il, inb(il)+1))/(cpn(il, inb(il)-1) & |
342 |
*(ph(il, inb(il)-1)-ph(il, inb(il)))) |
343 |
|
344 |
bx=0.1*ment(il, inb(il), inb(il))*(qent(il, inb(il), inb(il)) & |
345 |
-rr(il, inb(il)))/(ph(il, inb(il))-ph(il, inb(il)+1)) |
346 |
fr(il, inb(il))=fr(il, inb(il))-bx |
347 |
fr(il, inb(il)-1)=fr(il, inb(il)-1) & |
348 |
+bx*(ph(il, inb(il))-ph(il, inb(il)+1)) & |
349 |
/(ph(il, inb(il)-1)-ph(il, inb(il))) |
350 |
|
351 |
cx=0.1*ment(il, inb(il), inb(il))*(uent(il, inb(il), inb(il)) & |
352 |
-u(il, inb(il)))/(ph(il, inb(il))-ph(il, inb(il)+1)) |
353 |
fu(il, inb(il))=fu(il, inb(il))-cx |
354 |
fu(il, inb(il)-1)=fu(il, inb(il)-1) & |
355 |
+cx*(ph(il, inb(il))-ph(il, inb(il)+1)) & |
356 |
/(ph(il, inb(il)-1)-ph(il, inb(il))) |
357 |
|
358 |
dx=0.1*ment(il, inb(il), inb(il))*(vent(il, inb(il), inb(il)) & |
359 |
-v(il, inb(il)))/(ph(il, inb(il))-ph(il, inb(il)+1)) |
360 |
fv(il, inb(il))=fv(il, inb(il))-dx |
361 |
fv(il, inb(il)-1)=fv(il, inb(il)-1) & |
362 |
+dx*(ph(il, inb(il))-ph(il, inb(il)+1)) & |
363 |
/(ph(il, inb(il)-1)-ph(il, inb(il))) |
364 |
|
365 |
end do |
366 |
|
367 |
! *** homoginize tendencies below cloud base *** |
368 |
|
369 |
do il=1, ncum |
370 |
asum(il)=0.0 |
371 |
bsum(il)=0.0 |
372 |
csum(il)=0.0 |
373 |
dsum(il)=0.0 |
374 |
enddo |
375 |
|
376 |
do i=1, nl |
377 |
do il=1, ncum |
378 |
if (i <= (icb(il)-1)) then |
379 |
asum(il)=asum(il)+ft(il, i)*(ph(il, i)-ph(il, i+1)) |
380 |
bsum(il)=bsum(il)+fr(il, i)*(lv(il, i)+(cl-cpd)*(t(il, i)-t(il, 1))) & |
381 |
*(ph(il, i)-ph(il, i+1)) |
382 |
csum(il)=csum(il)+(lv(il, i)+(cl-cpd)*(t(il, i)-t(il, 1))) & |
383 |
*(ph(il, i)-ph(il, i+1)) |
384 |
dsum(il)=dsum(il)+t(il, i)*(ph(il, i)-ph(il, i+1))/th(il, i) |
385 |
endif |
386 |
enddo |
387 |
enddo |
388 |
|
389 |
do i=1, nl |
390 |
do il=1, ncum |
391 |
if (i <= (icb(il)-1)) then |
392 |
ft(il, i)=asum(il)*t(il, i)/(th(il, i)*dsum(il)) |
393 |
fr(il, i)=bsum(il)/csum(il) |
394 |
endif |
395 |
enddo |
396 |
enddo |
397 |
|
398 |
! *** reset counter and return *** |
399 |
|
400 |
do il=1, ncum |
401 |
sig(il, nd)=2.0 |
402 |
enddo |
403 |
|
404 |
do i=1, nd |
405 |
do il=1, ncum |
406 |
upwd(il, i)=0.0 |
407 |
dnwd(il, i)=0.0 |
408 |
enddo |
409 |
enddo |
410 |
|
411 |
do i=1, nl |
412 |
do il=1, ncum |
413 |
dnwd0(il, i)=-mp(il, i) |
414 |
enddo |
415 |
enddo |
416 |
do i=nl+1, nd |
417 |
do il=1, ncum |
418 |
dnwd0(il, i)=0. |
419 |
enddo |
420 |
enddo |
421 |
|
422 |
do i=1, nl |
423 |
do il=1, ncum |
424 |
if (i >= icb(il) .and. i <= inb(il)) then |
425 |
upwd(il, i)=0.0 |
426 |
dnwd(il, i)=0.0 |
427 |
endif |
428 |
enddo |
429 |
enddo |
430 |
|
431 |
do i=1, nl |
432 |
do k=1, nl |
433 |
do il=1, ncum |
434 |
up1(il, k, i)=0.0 |
435 |
dn1(il, k, i)=0.0 |
436 |
enddo |
437 |
enddo |
438 |
enddo |
439 |
|
440 |
do i=1, nl |
441 |
do k=i, nl |
442 |
do n=1, i-1 |
443 |
do il=1, ncum |
444 |
if (i >= icb(il).and.i <= inb(il).and.k <= inb(il)) then |
445 |
up1(il, k, i)=up1(il, k, i)+ment(il, n, k) |
446 |
dn1(il, k, i)=dn1(il, k, i)-ment(il, k, n) |
447 |
endif |
448 |
enddo |
449 |
enddo |
450 |
enddo |
451 |
enddo |
452 |
|
453 |
do i=2, nl |
454 |
do k=i, nl |
455 |
do il=1, ncum |
456 |
if (i <= inb(il).and.k <= inb(il)) then |
457 |
upwd(il, i)=upwd(il, i)+m(il, k)+up1(il, k, i) |
458 |
dnwd(il, i)=dnwd(il, i)+dn1(il, k, i) |
459 |
endif |
460 |
enddo |
461 |
enddo |
462 |
enddo |
463 |
|
464 |
!ccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccc |
465 |
! determination de la variation de flux ascendant entre |
466 |
! deux niveau non dilue mike |
467 |
!ccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccc |
468 |
|
469 |
do i=1, nl |
470 |
do il=1, ncum |
471 |
mike(il, i)=m(il, i) |
472 |
enddo |
473 |
enddo |
474 |
|
475 |
do i=nl+1, nd |
476 |
do il=1, ncum |
477 |
mike(il, i)=0. |
478 |
enddo |
479 |
enddo |
480 |
|
481 |
do i=1, nd |
482 |
do il=1, ncum |
483 |
ma(il, i)=0 |
484 |
enddo |
485 |
enddo |
486 |
|
487 |
do i=1, nl |
488 |
do j=i, nl |
489 |
do il=1, ncum |
490 |
ma(il, i)=ma(il, i)+m(il, j) |
491 |
enddo |
492 |
enddo |
493 |
enddo |
494 |
|
495 |
do i=nl+1, nd |
496 |
do il=1, ncum |
497 |
ma(il, i)=0. |
498 |
enddo |
499 |
enddo |
500 |
|
501 |
do i=1, nl |
502 |
do il=1, ncum |
503 |
if (i <= (icb(il)-1)) then |
504 |
ma(il, i)=0 |
505 |
endif |
506 |
enddo |
507 |
enddo |
508 |
|
509 |
!cccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccc |
510 |
! icb represente de niveau ou se trouve la |
511 |
! base du nuage, et inb le top du nuage |
512 |
!ccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccc |
513 |
|
514 |
do i=1, nd |
515 |
DO il=1, ncum |
516 |
rdcp=(rrd*(1.-rr(il, i))-rr(il, i)*rrv) & |
517 |
/(cpd*(1.-rr(il, i))+rr(il, i)*cpv) |
518 |
tls(il, i)=t(il, i)*(1000.0/p(il, i))**rdcp |
519 |
tps(il, i)=tp(il, i) |
520 |
end DO |
521 |
enddo |
522 |
|
523 |
! *** diagnose the in-cloud mixing ratio *** ! cld |
524 |
! *** of condensed water *** ! cld |
525 |
! ! cld |
526 |
|
527 |
do i=1, nd ! cld |
528 |
do il=1, ncum ! cld |
529 |
mac(il, i)=0.0 ! cld |
530 |
wa(il, i)=0.0 ! cld |
531 |
siga(il, i)=0.0 ! cld |
532 |
sax(il, i)=0.0 ! cld |
533 |
enddo ! cld |
534 |
enddo ! cld |
535 |
|
536 |
do i=minorig, nl ! cld |
537 |
do k=i+1, nl+1 ! cld |
538 |
do il=1, ncum ! cld |
539 |
if (i <= inb(il) .and. k <= (inb(il)+1)) then ! cld |
540 |
mac(il, i)=mac(il, i)+m(il, k) ! cld |
541 |
endif ! cld |
542 |
enddo ! cld |
543 |
enddo ! cld |
544 |
enddo ! cld |
545 |
|
546 |
do i=1, nl ! cld |
547 |
do j=1, i ! cld |
548 |
do il=1, ncum ! cld |
549 |
if (i >= icb(il) .and. i <= (inb(il)-1) & |
550 |
.and. j >= icb(il)) then ! cld |
551 |
sax(il, i)=sax(il, i)+rrd*(tvp(il, j)-tv(il, j)) & |
552 |
*(ph(il, j)-ph(il, j+1))/p(il, j) ! cld |
553 |
endif ! cld |
554 |
enddo ! cld |
555 |
enddo ! cld |
556 |
enddo ! cld |
557 |
|
558 |
do i=1, nl ! cld |
559 |
do il=1, ncum ! cld |
560 |
if (i >= icb(il) .and. i <= (inb(il)-1) & |
561 |
.and. sax(il, i) > 0.0) then ! cld |
562 |
wa(il, i)=sqrt(2.*sax(il, i)) ! cld |
563 |
endif ! cld |
564 |
enddo ! cld |
565 |
enddo ! cld |
566 |
|
567 |
do i=1, nl ! cld |
568 |
do il=1, ncum ! cld |
569 |
if (wa(il, i) > 0.0) & |
570 |
siga(il, i)=mac(il, i)/wa(il, i) & |
571 |
*rrd*tvp(il, i)/p(il, i)/100./delta ! cld |
572 |
siga(il, i) = min(siga(il, i), 1.0) ! cld |
573 |
!IM cf. FH |
574 |
if (iflag_clw == 0) then |
575 |
qcondc(il, i)=siga(il, i)*clw(il, i)*(1.-ep(il, i)) & |
576 |
+ (1.-siga(il, i))*qcond(il, i) ! cld |
577 |
else if (iflag_clw == 1) then |
578 |
qcondc(il, i)=qcond(il, i) ! cld |
579 |
endif |
580 |
|
581 |
enddo ! cld |
582 |
enddo ! cld |
583 |
|
584 |
end SUBROUTINE cv30_yield |
585 |
|
586 |
end module cv30_yield_m |