pkg/aim/phy_shtorh.F

C $Header: /u/gcmpack/models/MITgcmUV/pkg/aim/phy_shtorh.F,v 1.2 2001/02/02 21:36:29 adcroft Exp $
C $Name:  $
 
      SUBROUTINE SHTORH (IMODE,NGP,TA,PS,SIG,QA,RH,QSAT,myThid)
C--
C--   SUBROUTINE SHTORH (IMODE,NGP,TA,PS,SIG,QA,RH,QSAT)
C--
C--   Purpose: compute saturation specific humidity and 
C--            relative hum. from specific hum. (or viceversa)
C--   Input:   IMODE  : mode of operation
C--            NGP    : no. of grid-points
C--            TA     : abs. temperature
C--            PS     : normalized pressure   (=  p/1000_hPa) [if SIG < 0]
C--                   : normalized sfc. pres. (= ps/1000_hPa) [if SIG > 0]
C--            SIG    : sigma level
C--            QA     : specific humidity in g/kg [if IMODE > 0]
C--            RH     : relative humidity         [if IMODE < 0]
C--            QSAT   : saturation spec. hum. in g/kg 
C--   Output:  RH     : relative humidity         [if IMODE > 0] 
C--            QA     : specific humidity in g/kg [if IMODE < 0]
C--        


      IMPLICIT rEAL*8 (A-H,O-Z)
      INTEGER  myThid


CcnhDebugStarts
#include "SIZE.h"
CcnhDebugEnds
      REAL TA(NGP), PS(NGP), QA(NGP), RH(NGP), QSAT(NGP)
C
C---  1. Compute Qsat (g/kg) from T (degK) and normalized pres. P (= p/1000_hPa)
C        If SIG > 0, P = Ps * sigma, otherwise P = Ps(1) = const. 
C
      E0=  6.108 _d -3
      C1= 17.269 _d 0
      C2= 21.875 _d 0
      T0=273.16 _d 0
      T1= 35.86 _d 0
      T2=  7.66 _d 0
C 
      DO 110 J=1,NGP
        QSAT(J)=0.
        IF (TA(J).GE.T0) THEN
          QSAT(J)=E0*EXP(C1*(TA(J)-T0)/(TA(J)-T1))
        ELSE IF ( TA(J).GT.0.) then
          QSAT(J)=E0*EXP(C2*(TA(J)-T0)/(TA(J)-T2))
        ENDIF
  110 CONTINUE
C
      IF (SIG.LE.0.0) THEN
        DO 120 J=1,NGP
          QSAT(J)=622. _d 0*QSAT(J)/(PS(1)-0.378 _d 0*QSAT(J))
  120   CONTINUE
      ELSE
        DO 130 J=1,NGP
          QSAT(J)=622. _d 0*QSAT(J)/(SIG*PS(J)-0.378 _d 0*QSAT(J))
  130   CONTINUE
      ENDIF
chh      write(0,*) 'MAXVAL(QSAT)=',MAXVAL(QSAT)
chh      write(0,*) 'MINVAL(QSAT)=',MINVAL(QSAT)
C
C---  2. Compute rel.hum. RH=Q/Qsat (IMODE>0), or Q=RH*Qsat (IMODE<0)
C
      IF (IMODE.GT.0) THEN
        DO 210 J=1,NGP
          IF(QSAT(J).ne.0.) then
            RH(J)=QA(J)/QSAT(J)
          ELSE
            RH(J)=0.
          ENDIF
  210   CONTINUE
      ELSE IF (IMODE.LT.0) THEN
        DO 220 J=1,NGP
          QA(J)=RH(J)*QSAT(J)
  220   CONTINUE
      ENDIF
chh      write(0,*) 'MAXVAL(QA)=',MAXVAL(QA)
chh      write(0,*) 'MINVAL(QA)=',MINVAL(QA)
chh      write(0,*) 'MAXVAL(RH)=',MAXVAL(RH)
chh      write(0,*) 'MINVAL(RH)=',MINVAL(RH)
C                               
      RETURN
      END

      SUBROUTINE ZMEDDY (NLON,NLAT,FF,ZM,EDDY)


      IMPLICIT rEAL*8 (A-H,O-Z)


C
C *** Decompose a field into zonal-mean and eddy component
C
      REAL FF(NLON,NLAT), ZM(NLAT), EDDY(NLON,NLAT)
C
      RNLON=1./NLON
C
      DO 130 J=1,NLAT
C
        ZM(J)=0.
        DO 110 I=1,NLON
          ZM(J)=ZM(J)+FF(I,J)
 110    CONTINUE
        ZM(J)=ZM(J)*RNLON
C
        DO 120 I=1,NLON
          EDDY(I,J)=FF(I,J)-ZM(J)
 120    CONTINUE
C
 130  CONTINUE
C
C--
      RETURN
      END
C
1	C $Header: /u/gcmpack/models/MITgcmUV/pkg/aim/phy_shtorh.F,v 1.2 2001/02/02 21:36:29 adcroft Exp $
2	C $Name: $
3
4	SUBROUTINE SHTORH (IMODE,NGP,TA,PS,SIG,QA,RH,QSAT,myThid)
5	C--
6	C-- SUBROUTINE SHTORH (IMODE,NGP,TA,PS,SIG,QA,RH,QSAT)
7	C--
8	C-- Purpose: compute saturation specific humidity and
9	C-- relative hum. from specific hum. (or viceversa)
10	C-- Input: IMODE : mode of operation
11	C-- NGP : no. of grid-points
12	C-- TA : abs. temperature
13	C-- PS : normalized pressure (= p/1000_hPa) [if SIG < 0]
14	C-- : normalized sfc. pres. (= ps/1000_hPa) [if SIG > 0]
15	C-- SIG : sigma level
16	C-- QA : specific humidity in g/kg [if IMODE > 0]
17	C-- RH : relative humidity [if IMODE < 0]
18	C-- QSAT : saturation spec. hum. in g/kg
19	C-- Output: RH : relative humidity [if IMODE > 0]
20	C-- QA : specific humidity in g/kg [if IMODE < 0]
21	C--
22
23
24	IMPLICIT rEAL*8 (A-H,O-Z)
25	INTEGER myThid
26
27
28	CcnhDebugStarts
29	#include "SIZE.h"
30	CcnhDebugEnds
31	REAL TA(NGP), PS(NGP), QA(NGP), RH(NGP), QSAT(NGP)
32	C
33	C--- 1. Compute Qsat (g/kg) from T (degK) and normalized pres. P (= p/1000_hPa)
34	C If SIG > 0, P = Ps * sigma, otherwise P = Ps(1) = const.
35	C
36	E0= 6.108 _d -3
37	C1= 17.269 _d 0
38	C2= 21.875 _d 0
39	T0=273.16 _d 0
40	T1= 35.86 _d 0
41	T2= 7.66 _d 0
42	C
43	DO 110 J=1,NGP
44	QSAT(J)=0.
45	IF (TA(J).GE.T0) THEN
46	QSAT(J)=E0EXP(C1(TA(J)-T0)/(TA(J)-T1))
47	ELSE IF ( TA(J).GT.0.) then
48	QSAT(J)=E0EXP(C2(TA(J)-T0)/(TA(J)-T2))
49	ENDIF
50	110 CONTINUE
51	C
52	IF (SIG.LE.0.0) THEN
53	DO 120 J=1,NGP
54	QSAT(J)=622. _d 0QSAT(J)/(PS(1)-0.378 _d 0QSAT(J))
55	120 CONTINUE
56	ELSE
57	DO 130 J=1,NGP
58	QSAT(J)=622. _d 0QSAT(J)/(SIGPS(J)-0.378 _d 0*QSAT(J))
59	130 CONTINUE
60	ENDIF
61	chh write(0,*) 'MAXVAL(QSAT)=',MAXVAL(QSAT)
62	chh write(0,*) 'MINVAL(QSAT)=',MINVAL(QSAT)
63	C
64	C--- 2. Compute rel.hum. RH=Q/Qsat (IMODE>0), or Q=RH*Qsat (IMODE<0)
65	C
66	IF (IMODE.GT.0) THEN
67	DO 210 J=1,NGP
68	IF(QSAT(J).ne.0.) then
69	RH(J)=QA(J)/QSAT(J)
70	ELSE
71	RH(J)=0.
72	ENDIF
73	210 CONTINUE
74	ELSE IF (IMODE.LT.0) THEN
75	DO 220 J=1,NGP
76	QA(J)=RH(J)*QSAT(J)
77	220 CONTINUE
78	ENDIF
79	chh write(0,*) 'MAXVAL(QA)=',MAXVAL(QA)
80	chh write(0,*) 'MINVAL(QA)=',MINVAL(QA)
81	chh write(0,*) 'MAXVAL(RH)=',MAXVAL(RH)
82	chh write(0,*) 'MINVAL(RH)=',MINVAL(RH)
83	C
84	RETURN
85	END
86
87	SUBROUTINE ZMEDDY (NLON,NLAT,FF,ZM,EDDY)
88
89
90	IMPLICIT rEAL*8 (A-H,O-Z)
91
92
93	C
94	C *** Decompose a field into zonal-mean and eddy component
95	C
96	REAL FF(NLON,NLAT), ZM(NLAT), EDDY(NLON,NLAT)
97	C
98	RNLON=1./NLON
99	C
100	DO 130 J=1,NLAT
101	C
102	ZM(J)=0.
103	DO 110 I=1,NLON
104	ZM(J)=ZM(J)+FF(I,J)
105	110 CONTINUE
106	ZM(J)=ZM(J)*RNLON
107	C
108	DO 120 I=1,NLON
109	EDDY(I,J)=FF(I,J)-ZM(J)
110	120 CONTINUE
111	C
112	130 CONTINUE
113	C
114	C--
115	RETURN
116	END
117	C