1 | module sfluxi_mod |
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2 | |
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3 | implicit none |
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4 | |
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5 | contains |
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6 | |
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7 | SUBROUTINE SFLUXI(PLEV,TLEV,DTAUI,TAUCUMI,UBARI,RSFI,WNOI,DWNI, |
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8 | * COSBI,WBARI,NFLUXTOPI,NFLUXTOPI_nu, |
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9 | * FMNETI,fluxupi,fluxdni,fluxupi_nu, |
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10 | * FZEROI,TAUGSURF) |
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11 | |
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12 | use radinc_h, only: NTfac, NTstart, L_LEVELS, L_NSPECTI, L_NGAUSS |
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13 | use radinc_h, only: L_NLAYRAD, L_NLEVRAD |
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14 | use radcommon_h, only: planckir, tlimit,sigma, gweight |
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15 | use comcstfi_mod, only: pi |
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16 | use gfluxi_mod, only: gfluxi |
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17 | |
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18 | implicit none |
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19 | |
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20 | integer NLEVRAD, L, NW, NG, NTS, NTT |
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21 | |
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22 | real*8 TLEV(L_LEVELS), PLEV(L_LEVELS) |
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23 | real*8 TAUCUMI(L_LEVELS,L_NSPECTI,L_NGAUSS) |
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24 | real*8 FMNETI(L_NLAYRAD) |
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25 | real*8 WNOI(L_NSPECTI), DWNI(L_NSPECTI) |
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26 | real*8 DTAUI(L_NLAYRAD,L_NSPECTI,L_NGAUSS) |
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27 | real*8 FMUPI(L_NLEVRAD), FMDI(L_NLEVRAD) |
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28 | real*8 COSBI(L_NLAYRAD,L_NSPECTI,L_NGAUSS) |
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29 | real*8 WBARI(L_NLAYRAD,L_NSPECTI,L_NGAUSS) |
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30 | real*8 NFLUXTOPI |
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31 | real*8 NFLUXTOPI_nu(L_NSPECTI) |
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32 | real*8 fluxupi_nu(L_NLAYRAD,L_NSPECTI) |
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33 | real*8 FTOPUP |
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34 | |
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35 | real*8 UBARI, RSFI, TSURF, BSURF, TTOP, BTOP, TAUTOP |
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36 | real*8 PLANCK, PLTOP |
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37 | real*8 fluxupi(L_NLAYRAD), fluxdni(L_NLAYRAD) |
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38 | real*8 FZEROI(L_NSPECTI) |
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39 | real*8 taugsurf(L_NSPECTI,L_NGAUSS-1), fzero |
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40 | |
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41 | real*8 fup_tmp(L_NSPECTI),fdn_tmp(L_NSPECTI) |
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42 | real*8 PLANCKSUM,PLANCKREF |
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43 | |
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44 | ! AB : variables for interpolation |
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45 | REAL*8 C1 |
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46 | REAL*8 C2 |
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47 | REAL*8 P1 |
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48 | |
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49 | !======================================================================C |
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50 | |
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51 | NLEVRAD = L_NLEVRAD |
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52 | |
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53 | ! ZERO THE NET FLUXES |
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54 | NFLUXTOPI = 0.0D0 |
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55 | |
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56 | DO NW=1,L_NSPECTI |
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57 | NFLUXTOPI_nu(NW) = 0.0D0 |
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58 | DO L=1,L_NLAYRAD |
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59 | FLUXUPI_nu(L,NW) = 0.0D0 |
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60 | fup_tmp(nw)=0.0D0 |
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61 | fdn_tmp(nw)=0.0D0 |
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62 | END DO |
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63 | END DO |
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64 | |
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65 | DO L=1,L_NLAYRAD |
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66 | FMNETI(L) = 0.0D0 |
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67 | FLUXUPI(L) = 0.0D0 |
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68 | FLUXDNI(L) = 0.0D0 |
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69 | END DO |
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70 | |
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71 | ! WE NOW ENTER A MAJOR LOOP OVER SPECTRAL INTERVALS IN THE INFRARED |
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72 | ! TO CALCULATE THE NET FLUX IN EACH SPECTRAL INTERVAL |
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73 | |
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74 | TTOP = TLEV(2) ! JL12 why not (1) ??? |
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75 | TSURF = TLEV(L_LEVELS) |
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76 | |
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77 | NTS = int(TSURF*NTfac)-NTstart+1 |
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78 | NTT = int(TTOP *NTfac)-NTstart+1 |
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79 | |
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80 | !JL12 corrects the surface planck function so that its integral is equal to sigma Tsurf^4 |
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81 | !JL12 this ensure that no flux is lost due to: |
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82 | !JL12 -truncation of the planck function at high/low wavenumber |
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83 | !JL12 -numerical error during first spectral integration |
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84 | !JL12 -discrepancy between Tsurf and NTS/NTfac |
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85 | PLANCKSUM = 0.d0 |
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86 | PLANCKREF = TSURF * TSURF |
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87 | PLANCKREF = sigma * PLANCKREF * PLANCKREF |
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88 | |
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89 | DO NW=1,L_NSPECTI |
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90 | ! AB : PLANCKIR(NW,NTS) is replaced by P1, the linear interpolation result for a temperature TSURF |
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91 | C1 = TSURF * NTfac - int(TSURF * NTfac) |
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92 | P1 = (1.0D0 - C1) * PLANCKIR(NW,NTS) + C1 * PLANCKIR(NW,NTS+1) |
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93 | PLANCKSUM = PLANCKSUM + P1 * DWNI(NW) |
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94 | ENDDO |
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95 | |
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96 | PLANCKSUM = PLANCKREF / (PLANCKSUM * Pi) |
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97 | !JL12 |
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98 | |
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99 | DO 501 NW=1,L_NSPECTI |
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100 | ! SURFACE EMISSIONS - INDEPENDENT OF GAUSS POINTS |
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101 | ! AB : PLANCKIR(NW,NTS) is replaced by P1, the linear interpolation result for a temperature TSURF |
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102 | ! AB : idem for PLANCKIR(NW,NTT) and PLTOP |
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103 | C1 = TSURF * NTfac - int(TSURF * NTfac) |
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104 | C2 = TTOP * NTfac - int(TTOP * NTfac) |
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105 | P1 = (1.0D0 - C1) * PLANCKIR(NW,NTS) + C1 * PLANCKIR(NW,NTS+1) |
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106 | BSURF = (1. - RSFI) * P1 * PLANCKSUM |
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107 | PLTOP = (1.0D0 - C2) * PLANCKIR(NW,NTT) + C2*PLANCKIR(NW,NTT+1) |
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108 | |
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109 | ! If FZEROI(NW) = 1, then the k-coefficients are zero - skip to the |
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110 | ! special Gauss point at the end. |
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111 | FZERO = FZEROI(NW) |
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112 | |
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113 | IF(FZERO.ge.0.99) goto 40 |
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114 | |
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115 | DO NG=1,L_NGAUSS-1 |
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116 | |
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117 | if(TAUGSURF(NW,NG).lt. TLIMIT) then |
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118 | fzero = fzero + (1.0D0-FZEROI(NW))*GWEIGHT(NG) |
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119 | goto 30 |
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120 | end if |
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121 | |
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122 | ! SET UP THE UPPER AND LOWER BOUNDARY CONDITIONS ON THE IR |
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123 | ! CALCULATE THE DOWNWELLING RADIATION AT THE TOP OF THE MODEL |
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124 | ! OR THE TOP LAYER WILL COOL TO SPACE UNPHYSICALLY |
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125 | |
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126 | ! TAUTOP = DTAUI(1,NW,NG)*PLEV(2)/(PLEV(4)-PLEV(2)) |
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127 | TAUTOP = TAUCUMI(2,NW,NG) |
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128 | BTOP = (1.0D0-EXP(-TAUTOP/UBARI))*PLTOP |
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129 | |
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130 | ! WE CAN NOW SOLVE FOR THE COEFFICIENTS OF THE TWO STREAM |
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131 | ! CALL A SUBROUTINE THAT SOLVES FOR THE FLUX TERMS |
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132 | ! WITHIN EACH INTERVAL AT THE MIDPOINT WAVENUMBER |
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133 | |
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134 | CALL GFLUXI(NLEVRAD,TLEV,NW,DWNI(NW),DTAUI(1,NW,NG), |
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135 | * TAUCUMI(1,NW,NG), |
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136 | * WBARI(1,NW,NG),COSBI(1,NW,NG),UBARI,RSFI,BTOP, |
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137 | * BSURF,FTOPUP,FMUPI,FMDI) |
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138 | |
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139 | ! NOW CALCULATE THE CUMULATIVE IR NET FLUX |
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140 | NFLUXTOPI = NFLUXTOPI+FTOPUP*DWNI(NW)*GWEIGHT(NG) |
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141 | * * (1.0D0-FZEROI(NW)) |
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142 | |
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143 | ! and same thing by spectral band... (RDW) |
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144 | NFLUXTOPI_nu(NW) = NFLUXTOPI_nu(NW) + FTOPUP * DWNI(NW) |
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145 | * * GWEIGHT(NG) * (1.0D0-FZEROI(NW)) |
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146 | |
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147 | DO L=1,L_NLEVRAD-1 |
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148 | ! CORRECT FOR THE WAVENUMBER INTERVALS |
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149 | FMNETI(L) = FMNETI(L) + (FMUPI(L)-FMDI(L)) * DWNI(NW) |
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150 | * * GWEIGHT(NG)*(1.0D0-FZEROI(NW)) |
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151 | FLUXUPI(L) = FLUXUPI(L) + FMUPI(L)*DWNI(NW)*GWEIGHT(NG) |
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152 | * * (1.0D0-FZEROI(NW)) |
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153 | FLUXDNI(L) = FLUXDNI(L) + FMDI(L)*DWNI(NW)*GWEIGHT(NG) |
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154 | * * (1.0D0-FZEROI(NW)) |
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155 | ! and same thing by spectral band... (RW) |
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156 | FLUXUPI_nu(L,NW) = FLUXUPI_nu(L,NW) + FMUPI(L)*DWNI(NW) |
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157 | * * GWEIGHT(NG) * (1.0D0 - FZEROI(NW)) |
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158 | END DO |
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159 | |
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160 | 30 CONTINUE |
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161 | |
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162 | END DO !End NGAUSS LOOP |
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163 | |
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164 | 40 CONTINUE |
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165 | |
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166 | ! SPECIAL 17th Gauss point |
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167 | NG = L_NGAUSS |
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168 | |
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169 | ! TAUTOP = DTAUI(1,NW,NG)*PLEV(2)/(PLEV(4)-PLEV(2)) |
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170 | TAUTOP = TAUCUMI(2,NW,NG) |
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171 | BTOP = (1.0D0-EXP(-TAUTOP/UBARI))*PLTOP |
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172 | |
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173 | ! WE CAN NOW SOLVE FOR THE COEFFICIENTS OF THE TWO STREAM |
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174 | ! CALL A SUBROUTINE THAT SOLVES FOR THE FLUX TERMS |
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175 | ! WITHIN EACH INTERVAL AT THE MIDPOINT WAVENUMBER |
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176 | |
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177 | CALL GFLUXI(NLEVRAD,TLEV,NW,DWNI(NW),DTAUI(1,NW,NG), |
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178 | * TAUCUMI(1,NW,NG), |
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179 | * WBARI(1,NW,NG),COSBI(1,NW,NG),UBARI,RSFI,BTOP, |
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180 | * BSURF,FTOPUP,FMUPI,FMDI) |
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181 | |
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182 | ! NOW CALCULATE THE CUMULATIVE IR NET FLUX |
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183 | NFLUXTOPI = NFLUXTOPI+FTOPUP*DWNI(NW)*FZERO |
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184 | |
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185 | ! and same thing by spectral band... (RW) |
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186 | NFLUXTOPI_nu(NW) = NFLUXTOPI_nu(NW) |
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187 | * +FTOPUP*DWNI(NW)*FZERO |
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188 | |
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189 | DO L=1,L_NLEVRAD-1 |
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190 | ! CORRECT FOR THE WAVENUMBER INTERVALS |
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191 | FMNETI(L) = FMNETI(L)+(FMUPI(L)-FMDI(L))*DWNI(NW)*FZERO |
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192 | FLUXUPI(L) = FLUXUPI(L) + FMUPI(L)*DWNI(NW)*FZERO |
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193 | FLUXDNI(L) = FLUXDNI(L) + FMDI(L)*DWNI(NW)*FZERO |
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194 | ! and same thing by spectral band... (RW) |
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195 | FLUXUPI_nu(L,NW) = FLUXUPI_nu(L,NW) |
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196 | * + FMUPI(L) * DWNI(NW) * FZERO |
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197 | END DO |
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198 | |
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199 | 501 CONTINUE !End Spectral Interval LOOP |
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200 | ! *** END OF MAJOR SPECTRAL INTERVAL LOOP IN THE INFRARED**** |
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201 | |
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202 | END SUBROUTINE SFLUXI |
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203 | |
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204 | end module sfluxi_mod |
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