phylmd/Radlwsw/swtt1.f

SUBROUTINE swtt1(knu, kabs, kind, pu, ptr)
  USE dimens_m
  USE dimphy
  USE raddim
  IMPLICIT NONE

  ! -----------------------------------------------------------------------
  ! PURPOSE.
  ! --------
  ! THIS ROUTINE COMPUTES THE TRANSMISSION FUNCTIONS FOR ALL THE
  ! ABSORBERS (H2O, UNIFORMLY MIXED GASES, AND O3) IN THE TWO SPECTRAL
  ! INTERVALS.

  ! METHOD.
  ! -------

  ! TRANSMISSION FUNCTION ARE COMPUTED USING PADE APPROXIMANTS
  ! AND HORNER'S ALGORITHM.

  ! REFERENCE.
  ! ----------

  ! SEE RADIATION'S PART OF THE MODEL'S DOCUMENTATION AND
  ! ECMWF RESEARCH DEPARTMENT DOCUMENTATION OF THE IFS

  ! AUTHOR.
  ! -------
  ! JEAN-JACQUES MORCRETTE  *ECMWF*

  ! MODIFICATIONS.
  ! --------------
  ! ORIGINAL : 95-01-20
  ! -----------------------------------------------------------------------
  ! * ARGUMENTS:

  INTEGER knu ! INDEX OF THE SPECTRAL INTERVAL
  INTEGER kabs ! NUMBER OF ABSORBERS
  INTEGER kind(kabs) ! INDICES OF THE ABSORBERS
  DOUBLE PRECISION pu(kdlon, kabs) ! ABSORBER AMOUNT

  DOUBLE PRECISION ptr(kdlon, kabs) ! TRANSMISSION FUNCTION

  ! * LOCAL VARIABLES:

  DOUBLE PRECISION zr1(kdlon)
  DOUBLE PRECISION zr2(kdlon)
  DOUBLE PRECISION zu(kdlon)
  INTEGER jl, ja, i, j, ia

  ! * Prescribed Data:

  DOUBLE PRECISION apad(2, 3, 7), bpad(2, 3, 7), d(2, 3)
  SAVE apad, bpad, d
  DATA ((apad(1,i,j),i=1,3), j=1, 7)/0.912418292E+05, 0.000000000E-00, &
    0.925887084E-04, 0.723613782E+05, 0.000000000E-00, 0.129353723E-01, &
    0.596037057E+04, 0.000000000E-00, 0.800821928E+00, 0.000000000E-00, &
    0.000000000E-00, 0.242715973E+02, 0.000000000E-00, 0.000000000E-00, &
    0.878331486E+02, 0.000000000E-00, 0.000000000E-00, 0.191559725E+02, &
    0.000000000E-00, 0.000000000E-00, 0.000000000E+00/
  DATA ((apad(2,i,j),i=1,3), j=1, 7)/0.376655383E-08, 0.739646016E-08, &
    0.410177786E+03, 0.978576773E-04, 0.131849595E-03, 0.672595424E+02, &
    0.387714006E+00, 0.437772681E+00, 0.000000000E-00, 0.118461660E+03, &
    0.151345118E+03, 0.000000000E-00, 0.119079797E+04, 0.233628890E+04, &
    0.000000000E-00, 0.293353397E+03, 0.797219934E+03, 0.000000000E-00, &
    0.000000000E+00, 0.000000000E+00, 0.000000000E+00/

  DATA ((bpad(1,i,j),i=1,3), j=1, 7)/0.912418292E+05, 0.000000000E-00, &
    0.925887084E-04, 0.724555318E+05, 0.000000000E-00, 0.131812683E-01, &
    0.602593328E+04, 0.000000000E-00, 0.812706117E+00, 0.100000000E+01, &
    0.000000000E-00, 0.249863591E+02, 0.000000000E-00, 0.000000000E-00, &
    0.931071925E+02, 0.000000000E-00, 0.000000000E-00, 0.252233437E+02, &
    0.000000000E-00, 0.000000000E-00, 0.100000000E+01/
  DATA ((bpad(2,i,j),i=1,3), j=1, 7)/0.376655383E-08, 0.739646016E-08, &
    0.410177786E+03, 0.979023421E-04, 0.131861712E-03, 0.731185438E+02, &
    0.388611139E+00, 0.437949001E+00, 0.100000000E+01, 0.120291383E+03, &
    0.151692730E+03, 0.000000000E+00, 0.130531005E+04, 0.237071130E+04, &
    0.000000000E+00, 0.415049409E+03, 0.867914360E+03, 0.000000000E+00, &
    0.100000000E+01, 0.100000000E+01, 0.000000000E+00/

  DATA (d(1,i), i=1, 3)/0.00, 0.00, 0.00/
  DATA (d(2,i), i=1, 3)/0.000000000, 0.000000000, 0.800000000/
  ! -----------------------------------------------------------------------

  ! *         1.      HORNER'S ALGORITHM TO COMPUTE TRANSMISSION FUNCTION


  DO ja = 1, kabs
    ia = kind(ja)
    DO jl = 1, kdlon
      zu(jl) = pu(jl, ja)
      zr1(jl) = apad(knu, ia, 1) + zu(jl)*(apad(knu,ia,2)+zu(jl)*(apad(knu, &
        ia,3)+zu(jl)*(apad(knu,ia,4)+zu(jl)*(apad(knu,ia,5)+zu(jl)*(apad(knu, &
        ia,6)+zu(jl)*(apad(knu,ia,7)))))))

      zr2(jl) = bpad(knu, ia, 1) + zu(jl)*(bpad(knu,ia,2)+zu(jl)*(bpad(knu, &
        ia,3)+zu(jl)*(bpad(knu,ia,4)+zu(jl)*(bpad(knu,ia,5)+zu(jl)*(bpad(knu, &
        ia,6)+zu(jl)*(bpad(knu,ia,7)))))))


      ! *         2.      ADD THE BACKGROUND TRANSMISSION


      ptr(jl, ja) = (zr1(jl)/zr2(jl))*(1.-d(knu,ia)) + d(knu, ia)
    END DO
  END DO

  RETURN
END SUBROUTINE swtt1
1	guez	81	SUBROUTINE swtt1(knu, kabs, kind, pu, ptr)
2			USE dimens_m
3			USE dimphy
4			USE raddim
5			IMPLICIT NONE
6
7			! -----------------------------------------------------------------------
8			! PURPOSE.
9			! --------
10			! THIS ROUTINE COMPUTES THE TRANSMISSION FUNCTIONS FOR ALL THE
11			! ABSORBERS (H2O, UNIFORMLY MIXED GASES, AND O3) IN THE TWO SPECTRAL
12			! INTERVALS.
13
14			! METHOD.
15			! -------
16
17			! TRANSMISSION FUNCTION ARE COMPUTED USING PADE APPROXIMANTS
18			! AND HORNER'S ALGORITHM.
19
20			! REFERENCE.
21			! ----------
22
23			! SEE RADIATION'S PART OF THE MODEL'S DOCUMENTATION AND
24			! ECMWF RESEARCH DEPARTMENT DOCUMENTATION OF THE IFS
25
26			! AUTHOR.
27			! -------
28			! JEAN-JACQUES MORCRETTE ECMWF
29
30			! MODIFICATIONS.
31			! --------------
32			! ORIGINAL : 95-01-20
33			! -----------------------------------------------------------------------
34			! * ARGUMENTS:
35
36			INTEGER knu ! INDEX OF THE SPECTRAL INTERVAL
37			INTEGER kabs ! NUMBER OF ABSORBERS
38			INTEGER kind(kabs) ! INDICES OF THE ABSORBERS
39			DOUBLE PRECISION pu(kdlon, kabs) ! ABSORBER AMOUNT
40
41			DOUBLE PRECISION ptr(kdlon, kabs) ! TRANSMISSION FUNCTION
42
43			! * LOCAL VARIABLES:
44
45			DOUBLE PRECISION zr1(kdlon)
46			DOUBLE PRECISION zr2(kdlon)
47			DOUBLE PRECISION zu(kdlon)
48			INTEGER jl, ja, i, j, ia
49
50			! * Prescribed Data:
51
52			DOUBLE PRECISION apad(2, 3, 7), bpad(2, 3, 7), d(2, 3)
53			SAVE apad, bpad, d
54			DATA ((apad(1,i,j),i=1,3), j=1, 7)/0.912418292E+05, 0.000000000E-00, &
55			0.925887084E-04, 0.723613782E+05, 0.000000000E-00, 0.129353723E-01, &
56			0.596037057E+04, 0.000000000E-00, 0.800821928E+00, 0.000000000E-00, &
57			0.000000000E-00, 0.242715973E+02, 0.000000000E-00, 0.000000000E-00, &
58			0.878331486E+02, 0.000000000E-00, 0.000000000E-00, 0.191559725E+02, &
59			0.000000000E-00, 0.000000000E-00, 0.000000000E+00/
60			DATA ((apad(2,i,j),i=1,3), j=1, 7)/0.376655383E-08, 0.739646016E-08, &
61			0.410177786E+03, 0.978576773E-04, 0.131849595E-03, 0.672595424E+02, &
62			0.387714006E+00, 0.437772681E+00, 0.000000000E-00, 0.118461660E+03, &
63			0.151345118E+03, 0.000000000E-00, 0.119079797E+04, 0.233628890E+04, &
64			0.000000000E-00, 0.293353397E+03, 0.797219934E+03, 0.000000000E-00, &
65			0.000000000E+00, 0.000000000E+00, 0.000000000E+00/
66
67			DATA ((bpad(1,i,j),i=1,3), j=1, 7)/0.912418292E+05, 0.000000000E-00, &
68			0.925887084E-04, 0.724555318E+05, 0.000000000E-00, 0.131812683E-01, &
69			0.602593328E+04, 0.000000000E-00, 0.812706117E+00, 0.100000000E+01, &
70			0.000000000E-00, 0.249863591E+02, 0.000000000E-00, 0.000000000E-00, &
71			0.931071925E+02, 0.000000000E-00, 0.000000000E-00, 0.252233437E+02, &
72			0.000000000E-00, 0.000000000E-00, 0.100000000E+01/
73			DATA ((bpad(2,i,j),i=1,3), j=1, 7)/0.376655383E-08, 0.739646016E-08, &
74			0.410177786E+03, 0.979023421E-04, 0.131861712E-03, 0.731185438E+02, &
75			0.388611139E+00, 0.437949001E+00, 0.100000000E+01, 0.120291383E+03, &
76			0.151692730E+03, 0.000000000E+00, 0.130531005E+04, 0.237071130E+04, &
77			0.000000000E+00, 0.415049409E+03, 0.867914360E+03, 0.000000000E+00, &
78			0.100000000E+01, 0.100000000E+01, 0.000000000E+00/
79
80			DATA (d(1,i), i=1, 3)/0.00, 0.00, 0.00/
81			DATA (d(2,i), i=1, 3)/0.000000000, 0.000000000, 0.800000000/
82			! -----------------------------------------------------------------------
83
84			! * 1. HORNER'S ALGORITHM TO COMPUTE TRANSMISSION FUNCTION
85
86
87			DO ja = 1, kabs
88			ia = kind(ja)
89			DO jl = 1, kdlon
90			zu(jl) = pu(jl, ja)
91			zr1(jl) = apad(knu, ia, 1) + zu(jl)(apad(knu,ia,2)+zu(jl)(apad(knu, &
92			ia,3)+zu(jl)(apad(knu,ia,4)+zu(jl)(apad(knu,ia,5)+zu(jl)*(apad(knu, &
93			ia,6)+zu(jl)*(apad(knu,ia,7)))))))
94
95			zr2(jl) = bpad(knu, ia, 1) + zu(jl)(bpad(knu,ia,2)+zu(jl)(bpad(knu, &
96			ia,3)+zu(jl)(bpad(knu,ia,4)+zu(jl)(bpad(knu,ia,5)+zu(jl)*(bpad(knu, &
97			ia,6)+zu(jl)*(bpad(knu,ia,7)))))))
98
99
100			! * 2. ADD THE BACKGROUND TRANSMISSION
101
102
103			ptr(jl, ja) = (zr1(jl)/zr2(jl))*(1.-d(knu,ia)) + d(knu, ia)
104			END DO
105			END DO
106
107			RETURN
108			END SUBROUTINE swtt1