Sources/phylmd/stdlevvar.f

module stdlevvar_m

 IMPLICIT NONE

contains

  SUBROUTINE stdlevvar(klon, knon, nsrf, zxli, u1, v1, t1, q1, z1, ts1, &
       qsurf, rugos, psol, pat1, t_2m, q_2m, t_10m, q_10m, u_10m, ustar)

    ! From LMDZ4/libf/phylmd/stdlevvar.F90, version 1.3 2005/05/25 13:10:09

    use coefcdrag_m, only: coefcdrag
    USE suphec_m, ONLY: rg, rkappa

    ! Objet : calcul de la température et de l'humidité relative à 2 m
    ! et du module du vent à 10 m à partir des relations de
    ! Dyer-Businger et des équations de Louis.

    ! Reference: Hess, Colman and McAvaney (1995) 

    ! Author: I. Musat, 01.07.2002

    INTEGER, intent(in):: klon
    ! dimension de la grille physique (= nb_pts_latitude X nb_pts_longitude)

    INTEGER, intent(in):: knon
    ! knon----input-I- nombre de points pour un type de surface
    INTEGER, intent(in):: nsrf
    ! nsrf----input-I- indice pour le type de surface; voir indicesol.inc
    LOGICAL, intent(in):: zxli
    ! zxli----input-L- TRUE si calcul des cdrags selon Laurent Li
    REAL, dimension(klon), intent(in):: u1
    ! u1------input-R- vent zonal au 1er niveau du modele
    REAL, dimension(klon), intent(in):: v1
    ! v1------input-R- vent meridien au 1er niveau du modele
    REAL, dimension(klon), intent(in):: t1
    ! t1------input-R- temperature de l'air au 1er niveau du modele
    REAL, dimension(klon), intent(in):: q1
    ! q1------input-R- humidite relative au 1er niveau du modele
    REAL, dimension(klon), intent(in):: z1
    ! z1------input-R- geopotentiel au 1er niveau du modele
    REAL, dimension(klon), intent(in):: ts1
    ! ts1-----input-R- temperature de l'air a la surface
    REAL, dimension(klon), intent(in):: qsurf
     ! qsurf---input-R- humidite relative a la surface
    REAL, dimension(klon), intent(in):: rugos
    ! rugos---input-R- rugosite
   REAL, dimension(klon), intent(in):: psol
    ! psol----input-R- pression au sol
   REAL, dimension(klon), intent(in):: pat1
    ! pat1----input-R- pression au 1er niveau du modele

    REAL, dimension(klon), intent(out):: t_2m
    ! t_2m---output-R- temperature de l'air a 2m
    REAL, dimension(klon), intent(out):: q_2m
    ! q_2m---output-R- humidite relative a 2m
    REAL, dimension(klon), intent(out):: t_10m
    ! t_10m--output-R- temperature de l'air a 10m
    REAL, dimension(klon), intent(out):: q_10m
    ! q_10m--output-R- humidite specifique a 10m
    REAL, dimension(klon), intent(out):: u_10m
    ! u_10m--output-R- vitesse du vent a 10m
    REAL, intent(out):: ustar(klon) ! u*

    ! Local:

    ! RKAR : constante de von Karman
    REAL, PARAMETER:: RKAR=0.40
    ! niter : nombre iterations calcul "corrector"
    INTEGER, parameter:: niter=2, ncon=niter-1

    ! Variables locales
    INTEGER i, n
    REAL zref
    REAL, dimension(klon):: speed
    ! tpot : temperature potentielle
    REAL, dimension(klon):: tpot
    REAL, dimension(klon):: zri1, cdran
    REAL cdram(klon), cdrah(klon)
    ! ri1 : nb. de Richardson entre la surface --> la 1ere couche
    REAL, dimension(klon):: ri1 
    REAL, dimension(klon):: testar, qstar
    REAL, dimension(klon):: zdte, zdq 
    ! lmon : longueur de Monin-Obukhov selon Hess, Colman and McAvaney 
    DOUBLE PRECISION, dimension(klon):: lmon
    DOUBLE PRECISION, parameter:: eps=1.0D-20
    REAL, dimension(klon):: delu, delte, delq
    REAL, dimension(klon):: u_zref, te_zref, q_zref 
    REAL, dimension(klon):: temp, pref
    LOGICAL okri
    REAL, dimension(klon):: u_zref_p, temp_p, q_zref_p
    !convertgence
    REAL, dimension(klon):: te_zref_con, q_zref_con
    REAL, dimension(klon):: u_zref_c, temp_c, q_zref_c
    REAL, dimension(klon):: ok_pred, ok_corr

    !------------------------------------------------------------------------- 

    DO i=1, knon
       speed(i)=SQRT(u1(i)**2+v1(i)**2)
       ri1(i) = 0.0
    ENDDO

    okri=.FALSE.
    CALL coefcdrag(klon, knon, nsrf, zxli, speed, t1, q1, z1, psol, ts1, &
         qsurf, rugos, okri, ri1, cdram, cdrah, cdran, zri1, pref) 

    ! Star variables 

    DO i = 1, knon
       ri1(i) = zri1(i)
       tpot(i) = t1(i)* (psol(i)/pat1(i))**RKAPPA
       ustar(i) = sqrt(cdram(i) * speed(i) * speed(i))
       zdte(i) = tpot(i) - ts1(i)
       zdq(i) = max(q1(i), 0.0) - max(qsurf(i), 0.0)

       zdte(i) = sign(max(abs(zdte(i)), 1.e-10), zdte(i))

       testar(i) = (cdrah(i) * zdte(i) * speed(i))/ustar(i)
       qstar(i) = (cdrah(i) * zdq(i) * speed(i))/ustar(i)
       lmon(i) = (ustar(i) * ustar(i) * tpot(i))/ &
            (RKAR * RG * testar(i))
    ENDDO

    ! First aproximation of variables at zref  
    zref = 2.0
    CALL screenp(klon, knon, nsrf, speed, tpot, q1, &
         ts1, qsurf, rugos, lmon, &
         ustar, testar, qstar, zref, &
         delu, delte, delq)

    DO i = 1, knon
       u_zref(i) = delu(i)
       q_zref(i) = max(qsurf(i), 0.0) + delq(i)
       te_zref(i) = ts1(i) + delte(i)
       temp(i) = te_zref(i) * (psol(i)/pat1(i))**(-RKAPPA)
       q_zref_p(i) = q_zref(i)
       temp_p(i) = temp(i)
    ENDDO

    ! Iteration of the variables at the reference level zref :
    ! corrector calculation ; see Hess & McAvaney, 1995

    DO n = 1, niter
       okri=.TRUE.
       CALL screenc(klon, knon, nsrf, zxli, &
            u_zref, temp, q_zref, zref, &
            ts1, qsurf, rugos, psol, & 
            ustar, testar, qstar, okri, ri1, &
            pref, delu, delte, delq) 

       DO i = 1, knon
          u_zref(i) = delu(i)
          q_zref(i) = delq(i) + max(qsurf(i), 0.0)
          te_zref(i) = delte(i) + ts1(i) 

          ! return to normal temperature

          temp(i) = te_zref(i) * (psol(i)/pref(i))**(-RKAPPA)

          IF(n == ncon) THEN
             te_zref_con(i) = te_zref(i)
             q_zref_con(i) = q_zref(i)
          ENDIF
       ENDDO
    ENDDO

    ! verifier le critere de convergence : 0.25% pour te_zref et 5% pour qe_zref

    DO i = 1, knon
       q_zref_c(i) = q_zref(i)
       temp_c(i) = temp(i)

       ok_pred(i)=0.
       ok_corr(i)=1.

       t_2m(i) = temp_p(i) * ok_pred(i) + temp_c(i) * ok_corr(i)
       q_2m(i) = q_zref_p(i) * ok_pred(i) + q_zref_c(i) * ok_corr(i)
    ENDDO

    ! First aproximation of variables at zref  

    zref = 10.0
    CALL screenp(klon, knon, nsrf, speed, tpot, q1, &
         ts1, qsurf, rugos, lmon, &
         ustar, testar, qstar, zref, &
         delu, delte, delq)

    DO i = 1, knon
       u_zref(i) = delu(i)
       q_zref(i) = max(qsurf(i), 0.0) + delq(i)
       te_zref(i) = ts1(i) + delte(i)
       temp(i) = te_zref(i) * (psol(i)/pat1(i))**(-RKAPPA)
       u_zref_p(i) = u_zref(i)
    ENDDO

    ! Iteration of the variables at the reference level zref:
    ! corrector ; see Hess & McAvaney, 1995

    DO n = 1, niter
       okri=.TRUE.
       CALL screenc(klon, knon, nsrf, zxli, &
            u_zref, temp, q_zref, zref, &
            ts1, qsurf, rugos, psol, &
            ustar, testar, qstar, okri, ri1, &
            pref, delu, delte, delq)

       DO i = 1, knon
          u_zref(i) = delu(i)
          q_zref(i) = delq(i) + max(qsurf(i), 0.0)
          te_zref(i) = delte(i) + ts1(i)
          temp(i) = te_zref(i) * (psol(i)/pref(i))**(-RKAPPA)
       ENDDO
    ENDDO

    DO i = 1, knon
       u_zref_c(i) = u_zref(i)

       u_10m(i) = u_zref_p(i) * ok_pred(i) + u_zref_c(i) * ok_corr(i)

       q_zref_c(i) = q_zref(i)
       temp_c(i) = temp(i)
       t_10m(i) = temp_p(i) * ok_pred(i) + temp_c(i) * ok_corr(i)
       q_10m(i) = q_zref_p(i) * ok_pred(i) + q_zref_c(i) * ok_corr(i)
    ENDDO

  END subroutine stdlevvar

end module stdlevvar_m
1	module stdlevvar_m
2
3	IMPLICIT NONE
4
5	contains
6
7	SUBROUTINE stdlevvar(klon, knon, nsrf, zxli, u1, v1, t1, q1, z1, ts1, &
8	qsurf, rugos, psol, pat1, t_2m, q_2m, t_10m, q_10m, u_10m, ustar)
9
10	! From LMDZ4/libf/phylmd/stdlevvar.F90, version 1.3 2005/05/25 13:10:09
11
12	use coefcdrag_m, only: coefcdrag
13	USE suphec_m, ONLY: rg, rkappa
14
15	! Objet : calcul de la température et de l'humidité relative à 2 m
16	! et du module du vent à 10 m à partir des relations de
17	! Dyer-Businger et des équations de Louis.
18
19	! Reference: Hess, Colman and McAvaney (1995)
20
21	! Author: I. Musat, 01.07.2002
22
23	INTEGER, intent(in):: klon
24	! dimension de la grille physique (= nb_pts_latitude X nb_pts_longitude)
25
26	INTEGER, intent(in):: knon
27	! knon----input-I- nombre de points pour un type de surface
28	INTEGER, intent(in):: nsrf
29	! nsrf----input-I- indice pour le type de surface; voir indicesol.inc
30	LOGICAL, intent(in):: zxli
31	! zxli----input-L- TRUE si calcul des cdrags selon Laurent Li
32	REAL, dimension(klon), intent(in):: u1
33	! u1------input-R- vent zonal au 1er niveau du modele
34	REAL, dimension(klon), intent(in):: v1
35	! v1------input-R- vent meridien au 1er niveau du modele
36	REAL, dimension(klon), intent(in):: t1
37	! t1------input-R- temperature de l'air au 1er niveau du modele
38	REAL, dimension(klon), intent(in):: q1
39	! q1------input-R- humidite relative au 1er niveau du modele
40	REAL, dimension(klon), intent(in):: z1
41	! z1------input-R- geopotentiel au 1er niveau du modele
42	REAL, dimension(klon), intent(in):: ts1
43	! ts1-----input-R- temperature de l'air a la surface
44	REAL, dimension(klon), intent(in):: qsurf
45	! qsurf---input-R- humidite relative a la surface
46	REAL, dimension(klon), intent(in):: rugos
47	! rugos---input-R- rugosite
48	REAL, dimension(klon), intent(in):: psol
49	! psol----input-R- pression au sol
50	REAL, dimension(klon), intent(in):: pat1
51	! pat1----input-R- pression au 1er niveau du modele
52
53	REAL, dimension(klon), intent(out):: t_2m
54	! t_2m---output-R- temperature de l'air a 2m
55	REAL, dimension(klon), intent(out):: q_2m
56	! q_2m---output-R- humidite relative a 2m
57	REAL, dimension(klon), intent(out):: t_10m
58	! t_10m--output-R- temperature de l'air a 10m
59	REAL, dimension(klon), intent(out):: q_10m
60	! q_10m--output-R- humidite specifique a 10m
61	REAL, dimension(klon), intent(out):: u_10m
62	! u_10m--output-R- vitesse du vent a 10m
63	REAL, intent(out):: ustar(klon) ! u*
64
65	! Local:
66
67	! RKAR : constante de von Karman
68	REAL, PARAMETER:: RKAR=0.40
69	! niter : nombre iterations calcul "corrector"
70	INTEGER, parameter:: niter=2, ncon=niter-1
71
72	! Variables locales
73	INTEGER i, n
74	REAL zref
75	REAL, dimension(klon):: speed
76	! tpot : temperature potentielle
77	REAL, dimension(klon):: tpot
78	REAL, dimension(klon):: zri1, cdran
79	REAL cdram(klon), cdrah(klon)
80	! ri1 : nb. de Richardson entre la surface --> la 1ere couche
81	REAL, dimension(klon):: ri1
82	REAL, dimension(klon):: testar, qstar
83	REAL, dimension(klon):: zdte, zdq
84	! lmon : longueur de Monin-Obukhov selon Hess, Colman and McAvaney
85	DOUBLE PRECISION, dimension(klon):: lmon
86	DOUBLE PRECISION, parameter:: eps=1.0D-20
87	REAL, dimension(klon):: delu, delte, delq
88	REAL, dimension(klon):: u_zref, te_zref, q_zref
89	REAL, dimension(klon):: temp, pref
90	LOGICAL okri
91	REAL, dimension(klon):: u_zref_p, temp_p, q_zref_p
92	!convertgence
93	REAL, dimension(klon):: te_zref_con, q_zref_con
94	REAL, dimension(klon):: u_zref_c, temp_c, q_zref_c
95	REAL, dimension(klon):: ok_pred, ok_corr
96
97	!-------------------------------------------------------------------------
98
99	DO i=1, knon
100	speed(i)=SQRT(u1(i)2+v1(i)2)
101	ri1(i) = 0.0
102	ENDDO
103
104	okri=.FALSE.
105	CALL coefcdrag(klon, knon, nsrf, zxli, speed, t1, q1, z1, psol, ts1, &
106	qsurf, rugos, okri, ri1, cdram, cdrah, cdran, zri1, pref)
107
108	! Star variables
109
110	DO i = 1, knon
111	ri1(i) = zri1(i)
112	tpot(i) = t1(i)* (psol(i)/pat1(i))**RKAPPA
113	ustar(i) = sqrt(cdram(i) * speed(i) * speed(i))
114	zdte(i) = tpot(i) - ts1(i)
115	zdq(i) = max(q1(i), 0.0) - max(qsurf(i), 0.0)
116
117	zdte(i) = sign(max(abs(zdte(i)), 1.e-10), zdte(i))
118
119	testar(i) = (cdrah(i) * zdte(i) * speed(i))/ustar(i)
120	qstar(i) = (cdrah(i) * zdq(i) * speed(i))/ustar(i)
121	lmon(i) = (ustar(i) * ustar(i) * tpot(i))/ &
122	(RKAR * RG * testar(i))
123	ENDDO
124
125	! First aproximation of variables at zref
126	zref = 2.0
127	CALL screenp(klon, knon, nsrf, speed, tpot, q1, &
128	ts1, qsurf, rugos, lmon, &
129	ustar, testar, qstar, zref, &
130	delu, delte, delq)
131
132	DO i = 1, knon
133	u_zref(i) = delu(i)
134	q_zref(i) = max(qsurf(i), 0.0) + delq(i)
135	te_zref(i) = ts1(i) + delte(i)
136	temp(i) = te_zref(i) * (psol(i)/pat1(i))**(-RKAPPA)
137	q_zref_p(i) = q_zref(i)
138	temp_p(i) = temp(i)
139	ENDDO
140
141	! Iteration of the variables at the reference level zref :
142	! corrector calculation ; see Hess & McAvaney, 1995
143
144	DO n = 1, niter
145	okri=.TRUE.
146	CALL screenc(klon, knon, nsrf, zxli, &
147	u_zref, temp, q_zref, zref, &
148	ts1, qsurf, rugos, psol, &
149	ustar, testar, qstar, okri, ri1, &
150	pref, delu, delte, delq)
151
152	DO i = 1, knon
153	u_zref(i) = delu(i)
154	q_zref(i) = delq(i) + max(qsurf(i), 0.0)
155	te_zref(i) = delte(i) + ts1(i)
156
157	! return to normal temperature
158
159	temp(i) = te_zref(i) * (psol(i)/pref(i))**(-RKAPPA)
160
161	IF(n == ncon) THEN
162	te_zref_con(i) = te_zref(i)
163	q_zref_con(i) = q_zref(i)
164	ENDIF
165	ENDDO
166	ENDDO
167
168	! verifier le critere de convergence : 0.25% pour te_zref et 5% pour qe_zref
169
170	DO i = 1, knon
171	q_zref_c(i) = q_zref(i)
172	temp_c(i) = temp(i)
173
174	ok_pred(i)=0.
175	ok_corr(i)=1.
176
177	t_2m(i) = temp_p(i) * ok_pred(i) + temp_c(i) * ok_corr(i)
178	q_2m(i) = q_zref_p(i) * ok_pred(i) + q_zref_c(i) * ok_corr(i)
179	ENDDO
180
181	! First aproximation of variables at zref
182
183	zref = 10.0
184	CALL screenp(klon, knon, nsrf, speed, tpot, q1, &
185	ts1, qsurf, rugos, lmon, &
186	ustar, testar, qstar, zref, &
187	delu, delte, delq)
188
189	DO i = 1, knon
190	u_zref(i) = delu(i)
191	q_zref(i) = max(qsurf(i), 0.0) + delq(i)
192	te_zref(i) = ts1(i) + delte(i)
193	temp(i) = te_zref(i) * (psol(i)/pat1(i))**(-RKAPPA)
194	u_zref_p(i) = u_zref(i)
195	ENDDO
196
197	! Iteration of the variables at the reference level zref:
198	! corrector ; see Hess & McAvaney, 1995
199
200	DO n = 1, niter
201	okri=.TRUE.
202	CALL screenc(klon, knon, nsrf, zxli, &
203	u_zref, temp, q_zref, zref, &
204	ts1, qsurf, rugos, psol, &
205	ustar, testar, qstar, okri, ri1, &
206	pref, delu, delte, delq)
207
208	DO i = 1, knon
209	u_zref(i) = delu(i)
210	q_zref(i) = delq(i) + max(qsurf(i), 0.0)
211	te_zref(i) = delte(i) + ts1(i)
212	temp(i) = te_zref(i) * (psol(i)/pref(i))**(-RKAPPA)
213	ENDDO
214	ENDDO
215
216	DO i = 1, knon
217	u_zref_c(i) = u_zref(i)
218
219	u_10m(i) = u_zref_p(i) * ok_pred(i) + u_zref_c(i) * ok_corr(i)
220
221	q_zref_c(i) = q_zref(i)
222	temp_c(i) = temp(i)
223	t_10m(i) = temp_p(i) * ok_pred(i) + temp_c(i) * ok_corr(i)
224	q_10m(i) = q_zref_p(i) * ok_pred(i) + q_zref_c(i) * ok_corr(i)
225	ENDDO
226
227	END subroutine stdlevvar
228
229	end module stdlevvar_m