source: LMDZ6/branches/cirrus/libf/phylmd/coare_cp.F90 @ 5185

Last change on this file since 5185 was 4722, checked in by Laurent Fairhead, 14 months ago

Modification by O. Torres to the cdrag routines to include different bulk formulae
to calculate cdrag coefficients over ocean as well as an iteration of that
calculation.
The iteration is controlled by flag ok_cdrag_iter which if set to FALSE by default
to converge with previous results.
The choice of bulk formulae is set with the choix_bulk parameter
The number of iterations to run is set with nit_bulk
OT, PB, CD, LF

File size: 6.4 KB
Line 
1real function psit_30(zet)
2
3  real, intent(in) :: zet
4
5  if(zet<0) then
6     x=(1.-(15*zet))**.5
7     psik=2*log((1+x)/2)
8     x=(1.-(34.15*zet))**.3333
9     psic=1.5*log((1.+x+x*x)/3.)-sqrt(3.)*atan((1.+2.*x)/sqrt(3.))+4.*atan(1.)/sqrt(3.)
10     f=zet*zet/(1+zet*zet)
11     psit_30=(1-f)*psik+f*psic   
12
13  else
14     c=min(50.,.35*zet)
15     psit_30=-((1.+2./3.*zet)**1.5+.6667*(zet-14.28)/exp(c)+8.525)
16  endif
17end FUNCTION psit_30
18
19real function psiuo(zet)
20
21  real, intent(in) :: zet
22
23  if (zet<0) then
24
25     x=(1.-15.*zet)**.25
26     psik=2.*log((1.+x)/2.)+log((1.+x*x)/2.)-2.*atan(x)+2.*atan(1.)
27     x=(1.-10.15*zet)**.3333
28     psic=1.5*log((1.+x+x*x)/3.)-sqrt(3.)*atan((1.+2.*x)/sqrt(3.))+4.*atan(1.)/sqrt(3.)
29     f=zet*zet/(1+zet*zet)
30     psiuo=(1-f)*psik+f*psic                                               
31  else
32     c=min(50.,.35*zet)
33     psiuo=-((1+1.0*zet)**1.0+.667*(zet-14.28)/exp(c)+8.525)
34  endif
35END FUNCTION psiuo
36
37
38real function gen_q1(ts,p,dq)
39
40  real, intent(in) :: ts,p,dq
41  real es,qs
42
43  es = 6.112*exp(17.502*(ts-273.15)/(ts-32.18))*.98*(1.0007+3.46e-8*p)
44  qs = es*62.197/(p-37.8*es)
45
46  q1 = dq + qs 
47
48end function gen_q1
49
50
51
52
53subroutine coare_cp(du,dt,dq,&
54     t,q,&
55     zu,zt,zq,&
56     p,zi,&
57     nits,&
58     coeffs,rugosm,rugosh)
59  !     zo,tau,hsb,hlb,&
60  !     var)
61  !version with shortened iteration  modified Rt and Rq
62  !uses wave information wave period in s and wave ht in m
63  !no wave, standard coare 2.6 charnock:  jwave=0
64  !Oost et al.  zo=50/2/pi L (u*/c)**4.5 if jwave=1
65  !taylor and yelland  zo=1200 h*(L/h)**4.5 jwave=2
66  !
67  USE MODD_CSTS,       ONLY : XKARMAN, XG, XSTEFAN, XRD, XRV, XPI, &
68                            XLVTT, XCL, XCPD, XCPV, XRHOLW, XTT, &
69                            XP00
70
71  IMPLICIT NONE
72
73  real, intent(in) :: du,dt,dq,t,q
74  real, intent(in) :: zu,zt,zq,p,zi
75  integer, intent(in) :: nits
76  ! real, dimension (nits), intent(out) :: zo,tau,hsb,hlb
77  ! real, dimension(nits,3), intent(out) :: var
78  real, dimension(3), intent(out) :: coeffs
79  real, intent(out) :: rugosm
80  real, intent(out) :: rugosh
81
82  real, parameter ::  beta=1.2, von=.4, fdg = 1. ,&
83       tdk = 273.16, pi = 3.141593, grav = 9.82,&
84       rgas = 287.1
85
86  integer, dimension(3) :: shape_input
87
88  real bf, cc, rhoa, visa,&
89       u10, ut, uts, ut0, ug,&
90       cd10, ch10, ct, ct10,&
91       charn, ribu,&
92       l, l10, &
93       ribcu,rr,&
94       zet,zetu, zom10, zoh10, zot, zoq, zot10,&
95       cd, ch, le, cpa, cpv,&
96       usr,qsr,tsr,&
97       zom, t_c
98
99!, ZTWAVE, ZHWAVE, ZCWAVE, ZLWAVE
100
101
102
103
104  real old_usr, old_tsr, old_qsr,tmp
105
106  real, external :: psit_30, psiuo, grv
107  integer i,j,k
108!---------------- Rajout pour prendre en compte différent Z0 --------------------------------!
109!  INTEGER :: NGRVWAVES        ! Pour le choix du z0
110!  NGRVWAVES = 2
111!---------------------------------------------------------------------------------------------
112!-------------------- Attention Modif réalisée pas SURRR -------------------------------------
113!---------------------------------------------------------------------------------------------
114
115  Ribcu=-zu/zi/.004/Beta**3
116  cpa=1004.67
117
118  t_c = t - 273.15
119
120
121  Le=(2.501-.00237*(t_c-dt))*1e6
122
123
124  visa=1.326e-5*(1+6.542e-3*(t_c)+8.301e-6*t_c**2-4.84e-9*t_c**3)
125
126
127  cpv=cpa*(1+0.84*Q)
128  rhoa=P/(Rgas*t*(1+0.61*Q))
129
130
131
132
133
134
135  ug=.2
136
137  ut=sqrt(du*du+ug*ug)
138  ut=MAX(ut , 0.1 * MIN(10.,zu) )
139
140  u10=ut*log(10/1e-4)/log(zu/1e-4)
141  usr=.035*u10                              ! turbulent friction velocity (m/s), including gustiness
142  zom10=0.011*usr*usr/grav+0.11*visa/usr     ! roughness length for u (smith 88)
143  Cd10=(von/log(10/zom10))**2
144!  zoh10=0.40*visa/usr+1.4e-5
145!  Ch10=((von**2)/((log(10/zom10))*(log(10/zoh10)))) !ammener à devenir ca
146  Ch10=0.00115
147  Ct10=Ch10/sqrt(Cd10)
148  zot10=10/exp(von/Ct10)                    ! roughness length for t
149  Cd=(von/log(zu/zom10))**2
150  Ct=von/log(zt/zot10)
151  CC=von*Ct/Cd
152
153  ut0 = ut
154
155
156  ut = ut0
157  Ribu=grav*zu/t*(dt+.61*t*dq)/ut**2
158
159  if (Ribu .LT. 0) then
160     zetu=CC*Ribu/(1+Ribu/Ribcu)
161  else
162     zetu=CC*Ribu*(1+27/9*Ribu/CC)
163  endif
164
165  L10=zu/zetu
166
167  ! if (zetu .GT. 50) then
168  !    nits=1
169  ! endif
170
171  usr=ut*von/(log(zu/zom10)-psiuo(zetu))
172  tsr=dt*von*fdg/(log(zt/zot10)-psit_30(zt/L10))
173  qsr=dq*von*fdg/(log(zq/zot10)-psit_30(zq/L10))
174  !  tkt=.001
175
176  ! charnock constant - lin par morceau - constant
177  if ( ut <= 10. ) then
178     charn=0.011
179  else
180     if (ut .GT. 18) then
181        charn=0.018
182     else
183        charn=0.011+(ut-10)/(18-10)*(0.018-0.011)
184     endif
185  endif
186
187!  ZHWAVE = 0.018*ut*ut*(1.+0.015*ut)
188!  ZTWAVE = 0.729*ut
189!  ZCWAVE = XG*ZTWAVE/(2.*pi)
190!  ZLWAVE = ZTWAVE*ZCWAVE
191
192
193  !***************  bulk loop ************
194  do i=1, nits
195
196     zet=von*grav*zu/t*(tsr*(1+0.61*Q)+.61*t*qsr)/(usr*usr)/(1+0.61*Q)
197
198!     IF (NGRVWAVES==0) THEN
199!       zom = charn*usr*usr/XG + 0.11*visa/usr !Smith 1988
200!     ELSE IF (NGRVWAVES==1) THEN
201!       zom = (50./(2.*pi))*ZLWAVE*(usr/ZCWAVE)**4.5 &
202!               + 0.11*visa/usr                       !Oost et al. 2002 
203!     ELSE IF (NGRVWAVES==2) THEN
204!       zom = 1200.*ZHWAVE*(ZHWAVE/ZLWAVE)**4.5 &
205!               + 0.11*visa/usr                       !Taulor and Yelland 2001 
206!     ENDIF
207
208     zom=charn*usr*usr/grav+0.11*visa/usr
209
210     rr=zom*usr/visa
211     L=zu/zet
212     zoq=min(1.15e-4,5.5e-5/rr**.6)  ! a modifier
213     zot=zoq                         ! a modifier
214!     zot=0.40*visa/usr+1.4e-5
215
216     old_usr = usr
217     old_tsr = tsr
218     old_qsr = qsr
219
220     usr=ut*von/(log(zu/zom)-psiuo(zu/L))
221     tsr=dt*von*fdg/(log(zt/zot)-psit_30(zt/L))
222     qsr=dq*von*fdg/(log(zq/zoq)-psit_30(zq/L))
223
224     Bf=-grav/t*usr*(tsr+.61*t*qsr)
225
226     if (Bf .GT. 0) then
227        ug=Beta*(Bf*zi)**.333
228     else
229        ug=.2
230     endif
231
232     ut=sqrt(du*du+ug*ug)
233     ut=MAX(ut , 0.1 * MIN(10.,zu) )
234
235
236  enddo !bulk iter loop
237
238  ! coeffs(m1,m2,m3,m4,m5,1)=rhoa*usr*usr*du/ut !stress
239  ! coeffs(m1,m2,m3,m4,m5,2)=rhoa*cpa*usr*tsr
240  ! coeffs(m1,m2,m3,m4,m5,3)=rhoa*Le*usr*qsr
241
242  tmp = (von/(log(zu/zom)-psiuo(zu/L)) ) * ut / du
243
244  coeffs = [tmp**2,&
245       von*fdg/(log(zt/zot)-psit_30(zt/L)) * tmp,&
246       von*fdg/(log(zq/zoq)-psit_30(zq/L)) * tmp]
247
248  rugosm = zom
249  rugosh = zot
250
251
252end subroutine coare_cp
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