| [1529] | 1 | module radinc_h |
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| [135] | 2 | |
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| [1529] | 3 | implicit none |
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| [135] | 4 | |
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| [1529] | 5 | include "bands.h" |
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| [135] | 6 | |
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| [2972] | 7 | integer,save :: naerkind ! number of radiatively active aerosols |
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| 8 | ! set via inifis |
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| 9 | !$OMP THREADPRIVATE(naerkind) |
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| 10 | |
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| [486] | 11 | !====================================================================== |
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| [135] | 12 | ! |
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| [537] | 13 | ! RADINC.H |
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| [135] | 14 | ! |
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| 15 | ! Includes for the radiation code; RADIATION LAYERS, LEVELS, |
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| 16 | ! number of spectral intervals. . . |
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| 17 | ! |
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| [486] | 18 | !====================================================================== |
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| [135] | 19 | |
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| 20 | ! RADIATION parameters |
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| 21 | |
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| 22 | ! In radiation code, layer 1 corresponds to the stratosphere. Level |
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| 23 | ! 1 is the top of the stratosphere. The dummy layer is at the same |
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| 24 | ! temperature as the (vertically isothermal) stratosphere, and |
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| 25 | ! any time it is explicitly needed, the appropriate quantities will |
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| 26 | ! be dealt with (aka "top". . .) |
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| 27 | |
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| 28 | ! L_NLEVRAD corresponds to the surface - i.e., the GCM Level that |
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| 29 | ! is at the surface. PLEV(L_NLEVRAD) = P(J,I)+PTROP, |
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| 30 | ! PLEV(2) = PTROP, PLEV(1) = ptop |
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| 31 | |
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| 32 | ! L_NLAYRAD is the number of radiation code layers |
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| 33 | ! L_NLEVRAD is the number of radiation code levels. Level N is the |
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| 34 | ! top of layer N. |
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| 35 | ! |
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| 36 | ! L_NSPECTI is the number of IR spectral intervals |
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| 37 | ! L_NSPECTV is the number of Visual(or Solar) spectral intervals |
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| 38 | ! L_NGAUSS is the number of Gauss points for K-coefficients |
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| 39 | ! GAUSS POINT 17 (aka the last one) is the special case |
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| 40 | ! |
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| 41 | ! L_NPREF is the number of reference pressures that the |
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| 42 | ! k-coefficients are calculated on |
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| 43 | ! L_PINT is the number of Lagrange interpolated reference |
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| 44 | ! pressures for the gas k-coefficients - now for a |
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| 45 | ! smaller p-grid than before |
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| 46 | ! L_NTREF is the number of reference temperatures for the |
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| 47 | ! k-coefficients |
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| 48 | ! L_TAUMAX is the largest optical depth - larger ones are set |
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| 49 | ! to this value |
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| 50 | ! |
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| 51 | ! L_REFVAR The number of different mixing ratio values for |
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| 52 | ! the k-coefficients. Variable component of the mixture |
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| 53 | ! can in princple be anything: currently it's H2O. |
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| 54 | ! |
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| [728] | 55 | ! NAERKIND The number of radiatively active aerosol types |
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| 56 | ! |
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| [135] | 57 | ! NSIZEMAX The maximum number of aerosol particle sizes |
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| 58 | ! |
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| [537] | 59 | !---------------------------------------------------------------------- |
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| [135] | 60 | |
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| [1529] | 61 | integer,save :: L_NLAYRAD ! = nbp_lev ! set by ini_radinc_h |
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| 62 | integer,save :: L_LEVELS ! = 2*(nbp_lev-1)+3 ! set by ini_radinc_h |
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| 63 | integer,save :: L_NLEVRAD ! = nbp_lev+1 ! set by ini_radinc_h |
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| 64 | !$OMP THREADPRIVATE(L_NLAYRAD,L_LEVELS,L_NLEVRAD) |
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| [135] | 65 | |
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| [486] | 66 | ! These are set in sugas_corrk |
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| 67 | ! [uses allocatable arrays] -- AS 12/2011 |
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| [2026] | 68 | integer :: L_NPREF, L_NTREF, L_REFVAR, L_PINT, L_NGAUSS !L_NPREF, L_NTREF, L_REFVAR, L_PINT, L_NGAUSS read by master in sugas_corrk |
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| [470] | 69 | |
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| [135] | 70 | integer, parameter :: L_NSPECTI = NBinfrared |
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| 71 | integer, parameter :: L_NSPECTV = NBvisible |
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| 72 | |
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| [671] | 73 | ! integer, parameter :: NAERKIND = 2 ! set in scatterers.h |
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| [253] | 74 | real, parameter :: L_TAUMAX = 35 |
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| [135] | 75 | |
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| 76 | ! For Planck function integration: |
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| [2283] | 77 | ! ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
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| 78 | ! Integration boundary temperatures are NTstart/NTfac and Ntstop/NTfac |
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| 79 | ! -- JVO 20 : Now read boundary T and integration dT as inputs in callphys.def |
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| 80 | ! NTstart, Nstop and NTfac then set by ini_radinc_h |
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| 81 | ! Smart user can adjust values depending he's running hot or cold atm |
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| 82 | ! Default is wide range : 30K-1500K, with 0.1K step |
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| 83 | ! -> NTstart=300, Nstop=15000, NTfac=10 |
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| 84 | integer :: NTstart, NTstop |
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| 85 | real*8 :: NTfac |
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| [135] | 86 | |
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| [537] | 87 | ! Maximum number of grain size classes for aerosol convolution: |
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| 88 | ! This must correspond to size of largest dataset used for aerosol |
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| 89 | ! optical properties in datagcm folder. |
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| [135] | 90 | integer, parameter :: nsizemax = 60 |
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| 91 | |
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| [1520] | 92 | character(len=100),save :: corrkdir |
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| [1315] | 93 | !$OMP THREADPRIVATE(corrkdir) |
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| [135] | 94 | |
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| [1520] | 95 | character(len=100),save :: banddir |
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| [1315] | 96 | !$OMP THREADPRIVATE(banddir) |
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| [135] | 97 | |
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| [1529] | 98 | contains |
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| 99 | |
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| [2283] | 100 | subroutine ini_radinc_h(nbp_lev,tplanckmin,tplanckmax,dtplanck) |
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| [1529] | 101 | ! Initialize module variables |
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| 102 | implicit none |
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| 103 | integer,intent(in) :: nbp_lev |
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| [2283] | 104 | real*8, intent(in) :: tplanckmin |
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| 105 | real*8, intent(in) :: tplanckmax |
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| 106 | real*8, intent(in) :: dtplanck |
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| [1529] | 107 | |
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| 108 | L_NLAYRAD = nbp_lev |
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| [2283] | 109 | L_LEVELS = 2*(nbp_lev-1)+3 |
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| [1529] | 110 | L_NLEVRAD = nbp_lev+1 |
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| [2283] | 111 | |
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| 112 | NTfac = 1.D0 / dtplanck |
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| 113 | NTstart = int(tplanckmin * NTfac) |
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| 114 | NTstop = int(tplanckmax * NTfac) |
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| 115 | |
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| [1529] | 116 | end subroutine |
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| 117 | |
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| 118 | end module radinc_h |
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