source: trunk/LMDZ.GENERIC/libf/phystd/tpindex.F @ 3527

Last change on this file since 3527 was 2822, checked in by aslmd, 2 years ago

Fixed a real conversion

File size: 5.7 KB
RevLine 
[2582]1      module tpindex_mod
2     
3      implicit none
4     
5      contains
6     
[135]7      subroutine tpindex(pw,tw,qvar,pref,tref,wrefvar,LCOEF,MT,MP,
8     &     NVAR,wratio)
9
10!==================================================================
11!     
12!     Purpose
13!     -------
14!     Interpolate K-coefficients to the given P,T and Qvar values.
15!
16!     Notes
17!     -----
18!     The interpolation is the usual one in two dimensions given
19!     in "Numerical Recipes", where the "X" are P, the "Y" are
20!     T, and the F(X,Y) are the CO2 K-coefficients.
21!
22!     The interpolating box is:
23!
24!           (PL,TU)                        (PR,TU)
25!
26!                          (TW,PW)
27!
28!           
29!           (PL,TL)                        (PR,TL)
30!
31!      PL  - Pressure left
32!      PR  - Pressure right
33!      TL  - Temperature lower
34!      TU  - Temperature upper
35!      PW  - Pressure wanted
36!      TW  - Temperature wanted
37!
38!     Inputs
39!     ------
40!     PW                 - The pressure to interpolate to
41!     TW                 - The temperature to interpolate to
[2582]42!     Qvar               - The abundance to interpolate to
43!     Pref               - The tabulated (log) pressure grid
44!     Tref               - The tabulated temperature grid
45!     WREFVAR            - The tabulated abundance grid
[135]46!   
47!     Outputs
48!     -------
49!     MT                 - Temperature index (bottom left temperature)
50!                          of bounding box
51!     MP                 - Pressure index (bottom left pressure)
52!                          of bounding box
[2582]53!     NVAR               -  index (bottom left )
54!                          of bounding box
55!     LCOEF(4)           - Interpolation coefficients
56!     WRATIO             - weight for the interpolation of abundance
[135]57!
58!     Authors
59!     -------
60!     Adapted from the NASA Ames code by R. Wordsworth (2009)
61!     
62!==================================================================
63
[2582]64      use radinc_h, only: L_PINT, L_NTREF, L_REFVAR
[135]65
66      implicit none
67
[2582]68      REAL,INTENT(IN) :: Tref(L_NTREF)
69      REAL,INTENT(IN) :: pref(L_PINT)
70      REAL,INTENT(IN) :: wrefvar(L_REFVAR)
71      REAL,INTENT(IN) :: PW, TW, Qvar
[135]72
[2582]73      INTEGER,INTENT(OUT) :: MT, MP, NVAR
74      REAL,INTENT(OUT) :: LCOEF(4), wratio
75     
76      INTEGER :: N
77      REAL :: PWL ! local value for log10(PW)
78      REAL :: TWL ! local value for TW
79      REAL :: T ! linear interpolation weight along log(pressure)
80      REAL :: U ! linear interpolation weight along temperature
[135]81
[2582]82!     1. For the interpolation along temperature
[135]83!     Get the upper and lower temperature grid indicies that bound the
[2582]84!     requested temperature. If the sought temperature is below
[2821]85!     the T-grid minimum, assume that lower value. If the sought temperature
86!     is above the T-grid maximum, assume that maximum value.
[2582]87!     TW : temperature to interpolate to
88!     TREF : reference temperature array
89!     MT : index of TREF for (lower) bounding temperature
90!     U : weight for interpolation in temperature
[135]91
[2582]92      TWL = TW
93
94      IF(TWL.LT.TREF(1)) THEN
95        ! Below lowest tabulated temperature
[135]96        MT = 1
[2582]97        TWL=TREF(1)*1.00
98      ELSEIF(TWL.GE.TREF(L_NTREF)) THEN
99       ! Above highest tabulated temperature
[2821]100        MT=L_NTREF-1
101        TWL = TREF(L_NTREF)*1.00
[2582]102      ELSE
103        ! Regular case, find encompassing tabulated temperatures
[135]104        do n=1,L_NTREF-1
[2582]105          IF (TWL.GE.TREF(N) .and. TWL.LT.TREF(N+1)) THEN
[135]106            MT = n
[2582]107            EXIT
108          END IF
109        END DO
[135]110     
111      END IF
112
[2582]113!     weight for the temperature interpolation
114      U = (TWL-TREF(MT))/(TREF(MT+1)-TREF(MT))
[1600]115
[2582]116!     2. For interpolation along pressure
[135]117!     Get the upper and lower pressure grid indicies that bound the
[2582]118!     requested pressure. If the sought pressure is below
119!     the P-grid minimum, assume that lower value. If the sought pressure
[2821]120!     is above the P-grid maximum, assume that maximum value.
[135]121
[2582]122      PWL = log10(PW)
[135]123
[2582]124      IF(PWL.LT.PREF(1)) THEN
125        ! Below lowest tabulated pressure
126        MP = 1
127        PWL=Pref(1)*1.00
128      ELSEIF(PWL.GE.PREF(L_PINT)) THEN
129        ! Above highest tabulated pressure
130        MP = L_PINT-1
[2822]131        PWL = PREF(L_PINT)*1.00
[2582]132      ELSE
133        ! Regular case, find encompassing tabulated pressures
134        do n=1,L_PINT-1
135          IF (PWL.GE.PREF(N) .and. PWL.LT.PREF(N+1)) THEN
136            MP = n
137            EXIT
138          END IF
139        END DO
[1600]140     
[2582]141      END IF
[135]142
[2582]143!     weight for the pressure interpolation
[135]144      T = (PWL-PREF(MP))/(PREF(MP+1)-PREF(MP))
145
[2582]146!  Build the interpolation coefficients (bilinear in temperature-log(pressure))
[135]147      LCOEF(1) = (1.0-T)*(1.0-U)
148      LCOEF(2) = T*(1.0-U)
149      LCOEF(3) = T*U
150      LCOEF(4) = (1.0-T)*U
151
[2582]152!  3. For interpolation along abundances
[135]153!  Get the indicies for abundance of the varying species. There are 10 sets of
154!  k-coefficients with differing amounts of variable vs. constant gas.
155
[2582]156      IF(QVAR.LE.WREFVAR(1)) THEN
157        ! Below lowest tabulated abundance
[135]158        NVAR   = 1
[1600]159        WRATIO = 0.0D0      ! put all the weight on the first point
[2582]160      ELSEIF(QVAR.GE.WREFVAR(L_REFVAR)) THEN
161        ! Above highest tabulated abundance
[1600]162        NVAR   = L_REFVAR-1 ! TB16 in order to not oversize NVAr when doing
163                                  !NVAR+1
164        WRATIO = 1.00D0     ! put all the weight on the last point
[135]165      ELSE
[2582]166        ! Regular case, find encompassing tabulated abundances
167        ! and compute corresponding weight
[135]168        DO N=2,L_REFVAR
[2582]169          IF(QVAR.GE.WREFVAR(N-1) .and. QVAR.LT.WREFVAR(N)) THEN
[135]170            NVAR   = N-1
171            WRATIO = (QVAR - WREFVAR(N-1))/(WREFVAR(N) - WREFVAR(N-1))
[2582]172            EXIT
[135]173          END IF
174        END DO
175      END IF
176
[2582]177      end subroutine tpindex
178     
179      end module tpindex_mod
180     
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