1 | ! radiation_two_stream.F90 - Compute two-stream coefficients |
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2 | |
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3 | ! (C) Copyright 2014- ECMWF. |
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4 | |
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5 | ! This software is licensed under the terms of the Apache Licence Version 2.0 |
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6 | ! which can be obtained at http://www.apache.org/licenses/LICENSE-2.0. |
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7 | |
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8 | ! In applying this licence, ECMWF does not waive the privileges and immunities |
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9 | ! granted to it by virtue of its status as an intergovernmental organisation |
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10 | ! nor does it submit to any jurisdiction. |
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11 | |
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12 | ! Author: Robin Hogan |
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13 | ! Email: r.j.hogan@ecmwf.int |
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14 | |
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15 | ! Modifications |
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16 | ! 2017-05-04 P Dueben/R Hogan Use JPRD where double precision essential |
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17 | ! 2017-07-12 R Hogan Optimized LW coeffs in low optical depth case |
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18 | ! 2017-07-26 R Hogan Added calc_frac_scattered_diffuse_sw routine |
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19 | ! 2017-10-23 R Hogan Renamed single-character variables |
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20 | ! 2021-02-19 R Hogan Security for shortwave singularity |
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21 | |
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22 | module radiation_two_stream |
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23 | |
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24 | use parkind1, only : jprb, jprd |
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25 | |
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26 | implicit none |
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27 | public |
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28 | |
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29 | ! Elsasser's factor: the effective factor by which the zenith |
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30 | ! optical depth needs to be multiplied to account for longwave |
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31 | ! transmission at all angles through the atmosphere. Alternatively |
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32 | ! think of acos(1/lw_diffusivity) to be the effective zenith angle |
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33 | ! of longwave radiation. |
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34 | real(jprd), parameter :: LwDiffusivity = 1.66_jprd |
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35 | real(jprb), parameter :: LwDiffusivityWP = 1.66_jprb ! Working precision version |
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36 | |
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37 | ! Shortwave diffusivity factor assumes hemispheric isotropy, assumed |
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38 | ! by Zdunkowski's scheme and most others; note that for efficiency |
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39 | ! this parameter is not used in the calculation of the gamma values, |
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40 | ! but is used in the SPARTACUS solver. |
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41 | real(jprb), parameter :: SwDiffusivity = 2.00_jprb |
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42 | |
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43 | ! The routines in this module can be called millions of times, so |
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44 | !calling Dr Hook for each one may be a significant overhead. |
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45 | !Uncomment the following to turn Dr Hook on. |
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46 | !#define DO_DR_HOOK_TWO_STREAM |
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47 | |
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48 | contains |
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49 | |
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50 | #ifdef FAST_EXPONENTIAL |
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51 | !--------------------------------------------------------------------- |
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52 | ! Fast exponential for negative arguments: a Pade approximant that |
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53 | ! doesn't go negative for negative arguments, applied to arg/8, and |
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54 | ! the result is then squared three times |
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55 | elemental function exp_fast(arg) result(ex) |
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56 | real(jprd) :: arg, ex |
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57 | ex = 1.0_jprd / (1.0_jprd + arg*(-0.125_jprd & |
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58 | + arg*(0.0078125_jprd - 0.000325520833333333_jprd * arg))) |
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59 | ex = ex*ex |
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60 | ex = ex*ex |
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61 | ex = ex*ex |
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62 | end function exp_fast |
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63 | #else |
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64 | #define exp_fast exp |
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65 | #endif |
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66 | |
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67 | !--------------------------------------------------------------------- |
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68 | ! Calculate the two-stream coefficients gamma1 and gamma2 for the |
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69 | ! longwave |
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70 | subroutine calc_two_stream_gammas_lw(ng, ssa, g, & |
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71 | & gamma1, gamma2) |
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72 | |
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73 | #ifdef DO_DR_HOOK_TWO_STREAM |
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74 | use yomhook, only : lhook, dr_hook |
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75 | #endif |
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76 | |
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77 | integer, intent(in) :: ng |
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78 | ! Sngle scattering albedo and asymmetry factor: |
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79 | real(jprb), intent(in), dimension(:) :: ssa, g |
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80 | real(jprb), intent(out), dimension(:) :: gamma1, gamma2 |
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81 | |
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82 | real(jprb) :: factor |
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83 | |
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84 | integer :: jg |
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85 | |
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86 | #ifdef DO_DR_HOOK_TWO_STREAM |
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87 | real(jprb) :: hook_handle |
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88 | |
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89 | if (lhook) call dr_hook('radiation_two_stream:calc_two_stream_gammas_lw',0,hook_handle) |
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90 | #endif |
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91 | ! Added for DWD (2020) |
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92 | !NEC$ shortloop |
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93 | DO jg = 1, ng |
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94 | ! Fu et al. (1997), Eq 2.9 and 2.10: |
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95 | ! gamma1(jg) = LwDiffusivity * (1.0_jprb - 0.5_jprb*ssa(jg) & |
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96 | ! & * (1.0_jprb + g(jg))) |
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97 | ! gamma2(jg) = LwDiffusivity * 0.5_jprb * ssa(jg) & |
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98 | ! & * (1.0_jprb - g(jg)) |
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99 | ! Reduce number of multiplications |
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100 | factor = (LwDiffusivity * 0.5_jprb) * ssa(jg) |
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101 | gamma1(jg) = LwDiffusivity - factor*(1.0_jprb + g(jg)) |
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102 | gamma2(jg) = factor * (1.0_jprb - g(jg)) |
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103 | end do |
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104 | |
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105 | #ifdef DO_DR_HOOK_TWO_STREAM |
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106 | if (lhook) call dr_hook('radiation_two_stream:calc_two_stream_gammas_lw',1,hook_handle) |
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107 | #endif |
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108 | |
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109 | end subroutine calc_two_stream_gammas_lw |
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110 | |
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111 | |
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112 | !--------------------------------------------------------------------- |
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113 | ! Calculate the two-stream coefficients gamma1-gamma4 in the |
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114 | ! shortwave |
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115 | subroutine calc_two_stream_gammas_sw(ng, mu0, ssa, g, & |
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116 | & gamma1, gamma2, gamma3) |
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117 | |
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118 | #ifdef DO_DR_HOOK_TWO_STREAM |
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119 | use yomhook, only : lhook, dr_hook |
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120 | #endif |
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121 | |
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122 | integer, intent(in) :: ng |
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123 | ! Cosine of solar zenith angle, single scattering albedo and |
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124 | ! asymmetry factor: |
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125 | real(jprb), intent(in) :: mu0 |
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126 | real(jprb), intent(in), dimension(:) :: ssa, g |
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127 | real(jprb), intent(out), dimension(:) :: gamma1, gamma2, gamma3 |
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128 | |
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129 | real(jprb) :: factor |
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130 | |
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131 | integer :: jg |
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132 | |
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133 | #ifdef DO_DR_HOOK_TWO_STREAM |
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134 | real(jprb) :: hook_handle |
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135 | |
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136 | if (lhook) call dr_hook('radiation_two_stream:calc_two_stream_gammas_sw',0,hook_handle) |
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137 | #endif |
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138 | |
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139 | ! Zdunkowski "PIFM" (Zdunkowski et al., 1980; Contributions to |
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140 | ! Atmospheric Physics 53, 147-66) |
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141 | ! Added for DWD (2020) |
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142 | !NEC$ shortloop |
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143 | DO jg = 1, ng |
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144 | ! gamma1(jg) = 2.0_jprb - ssa(jg) * (1.25_jprb + 0.75_jprb*g(jg)) |
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145 | ! gamma2(jg) = 0.75_jprb *(ssa(jg) * (1.0_jprb - g(jg))) |
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146 | ! gamma3(jg) = 0.5_jprb - (0.75_jprb*mu0)*g(jg) |
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147 | ! Optimized version: |
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148 | factor = 0.75_jprb*g(jg) |
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149 | gamma1(jg) = 2.0_jprb - ssa(jg) * (1.25_jprb + factor) |
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150 | gamma2(jg) = ssa(jg) * (0.75_jprb - factor) |
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151 | gamma3(jg) = 0.5_jprb - mu0*factor |
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152 | end do |
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153 | |
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154 | #ifdef DO_DR_HOOK_TWO_STREAM |
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155 | if (lhook) call dr_hook('radiation_two_stream:calc_two_stream_gammas_sw',1,hook_handle) |
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156 | #endif |
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157 | |
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158 | end subroutine calc_two_stream_gammas_sw |
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159 | |
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160 | |
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161 | !--------------------------------------------------------------------- |
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162 | ! Compute the longwave reflectance and transmittance to diffuse |
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163 | ! radiation using the Meador & Weaver formulas, as well as the |
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164 | ! upward flux at the top and the downward flux at the base of the |
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165 | ! layer due to emission from within the layer assuming a linear |
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166 | ! variation of Planck function within the layer. |
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167 | subroutine calc_reflectance_transmittance_lw(ng, & |
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168 | & od, gamma1, gamma2, planck_top, planck_bot, & |
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169 | & reflectance, transmittance, source_up, source_dn) |
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170 | |
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171 | #ifdef DO_DR_HOOK_TWO_STREAM |
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172 | use yomhook, only : lhook, dr_hook |
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173 | #endif |
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174 | |
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175 | integer, intent(in) :: ng |
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176 | |
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177 | ! Optical depth and single scattering albedo |
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178 | real(jprb), intent(in), dimension(ng) :: od |
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179 | |
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180 | ! The two transfer coefficients from the two-stream |
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181 | ! differentiatial equations (computed by |
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182 | ! calc_two_stream_gammas_lw) |
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183 | real(jprb), intent(in), dimension(ng) :: gamma1, gamma2 |
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184 | |
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185 | ! The Planck terms (functions of temperature) at the top and |
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186 | ! bottom of the layer |
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187 | real(jprb), intent(in), dimension(ng) :: planck_top, planck_bot |
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188 | |
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189 | ! The diffuse reflectance and transmittance, i.e. the fraction of |
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190 | ! diffuse radiation incident on a layer from either top or bottom |
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191 | ! that is reflected back or transmitted through |
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192 | real(jprb), intent(out), dimension(ng) :: reflectance, transmittance |
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193 | |
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194 | ! The upward emission at the top of the layer and the downward |
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195 | ! emission at its base, due to emission from within the layer |
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196 | real(jprb), intent(out), dimension(ng) :: source_up, source_dn |
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197 | |
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198 | real(jprd) :: k_exponent, reftrans_factor |
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199 | real(jprd) :: exponential ! = exp(-k_exponent*od) |
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200 | real(jprd) :: exponential2 ! = exp(-2*k_exponent*od) |
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201 | |
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202 | real(jprd) :: coeff, coeff_up_top, coeff_up_bot, coeff_dn_top, coeff_dn_bot |
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203 | |
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204 | integer :: jg |
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205 | |
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206 | #ifdef DO_DR_HOOK_TWO_STREAM |
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207 | real(jprb) :: hook_handle |
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208 | |
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209 | if (lhook) call dr_hook('radiation_two_stream:calc_reflectance_transmittance_lw',0,hook_handle) |
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210 | #endif |
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211 | |
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212 | ! Added for DWD (2020) |
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213 | !NEC$ shortloop |
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214 | DO jg = 1, ng |
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215 | if (od(jg) > 1.0e-3_jprd) then |
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216 | k_exponent = sqrt(max((gamma1(jg) - gamma2(jg)) * (gamma1(jg) + gamma2(jg)), & |
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217 | 1.E-12_jprd)) ! Eq 18 of Meador & Weaver (1980) |
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218 | exponential = exp_fast(-k_exponent*od(jg)) |
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219 | exponential2 = exponential*exponential |
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220 | reftrans_factor = 1.0 / (k_exponent + gamma1(jg) + (k_exponent - gamma1(jg))*exponential2) |
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221 | ! Meador & Weaver (1980) Eq. 25 |
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222 | reflectance(jg) = gamma2(jg) * (1.0_jprd - exponential2) * reftrans_factor |
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223 | ! Meador & Weaver (1980) Eq. 26 |
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224 | transmittance(jg) = 2.0_jprd * k_exponent * exponential * reftrans_factor |
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225 | |
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226 | ! Compute upward and downward emission assuming the Planck |
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227 | ! function to vary linearly with optical depth within the layer |
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228 | ! (e.g. Wiscombe , JQSRT 1976). |
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229 | |
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230 | ! Stackhouse and Stephens (JAS 1991) Eqs 5 & 12 |
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231 | coeff = (planck_bot(jg)-planck_top(jg)) / (od(jg)*(gamma1(jg)+gamma2(jg))) |
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232 | coeff_up_top = coeff + planck_top(jg) |
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233 | coeff_up_bot = coeff + planck_bot(jg) |
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234 | coeff_dn_top = -coeff + planck_top(jg) |
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235 | coeff_dn_bot = -coeff + planck_bot(jg) |
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236 | source_up(jg) = coeff_up_top - reflectance(jg) * coeff_dn_top - transmittance(jg) * coeff_up_bot |
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237 | source_dn(jg) = coeff_dn_bot - reflectance(jg) * coeff_up_bot - transmittance(jg) * coeff_dn_top |
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238 | else |
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239 | k_exponent = sqrt(max((gamma1(jg) - gamma2(jg)) * (gamma1(jg) + gamma2(jg)), & |
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240 | 1.E-12_jprd)) ! Eq 18 of Meador & Weaver (1980) |
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241 | reflectance(jg) = gamma2(jg) * od(jg) |
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242 | transmittance(jg) = (1.0_jprb - k_exponent*od(jg)) / (1.0_jprb + od(jg)*(gamma1(jg)-k_exponent)) |
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243 | source_up(jg) = (1.0_jprb - reflectance(jg) - transmittance(jg)) & |
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244 | & * 0.5 * (planck_top(jg) + planck_bot(jg)) |
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245 | source_dn(jg) = source_up(jg) |
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246 | end if |
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247 | end do |
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248 | |
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249 | #ifdef DO_DR_HOOK_TWO_STREAM |
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250 | if (lhook) call dr_hook('radiation_two_stream:calc_reflectance_transmittance_lw',1,hook_handle) |
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251 | #endif |
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252 | |
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253 | end subroutine calc_reflectance_transmittance_lw |
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254 | |
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255 | |
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256 | |
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257 | !--------------------------------------------------------------------- |
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258 | ! As calc_reflectance_transmittance_lw but for an isothermal layer |
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259 | subroutine calc_reflectance_transmittance_isothermal_lw(ng, & |
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260 | & od, gamma1, gamma2, planck, & |
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261 | & reflectance, transmittance, source) |
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262 | |
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263 | #ifdef DO_DR_HOOK_TWO_STREAM |
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264 | use yomhook, only : lhook, dr_hook |
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265 | #endif |
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266 | |
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267 | integer, intent(in) :: ng |
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268 | |
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269 | ! Optical depth and single scattering albedo |
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270 | real(jprb), intent(in), dimension(ng) :: od |
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271 | |
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272 | ! The two transfer coefficients from the two-stream |
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273 | ! differentiatial equations (computed by |
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274 | ! calc_two_stream_gammas_lw) |
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275 | real(jprb), intent(in), dimension(ng) :: gamma1, gamma2 |
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276 | |
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277 | ! The Planck terms (functions of temperature) constant through the |
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278 | ! layer |
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279 | real(jprb), intent(in), dimension(ng) :: planck |
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280 | |
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281 | ! The diffuse reflectance and transmittance, i.e. the fraction of |
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282 | ! diffuse radiation incident on a layer from either top or bottom |
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283 | ! that is reflected back or transmitted through |
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284 | real(jprb), intent(out), dimension(ng) :: reflectance, transmittance |
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285 | |
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286 | ! The upward emission at the top of the layer and the downward |
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287 | ! emission at its base, due to emission from within the layer |
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288 | real(jprb), intent(out), dimension(ng) :: source |
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289 | |
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290 | real(jprd) :: k_exponent, reftrans_factor |
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291 | real(jprd) :: exponential ! = exp(-k_exponent*od) |
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292 | real(jprd) :: exponential2 ! = exp(-2*k_exponent*od) |
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293 | |
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294 | integer :: jg |
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295 | |
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296 | #ifdef DO_DR_HOOK_TWO_STREAM |
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297 | real(jprb) :: hook_handle |
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298 | |
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299 | if (lhook) call dr_hook('radiation_two_stream:calc_reflectance_transmittance_isothermal_lw',0,hook_handle) |
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300 | #endif |
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301 | |
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302 | ! Added for DWD (2020) |
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303 | !NEC$ shortloop |
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304 | DO jg = 1, ng |
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305 | k_exponent = sqrt(max((gamma1(jg) - gamma2(jg)) * (gamma1(jg) + gamma2(jg)), & |
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306 | 1.E-12_jprd)) ! Eq 18 of Meador & Weaver (1980) |
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307 | exponential = exp_fast(-k_exponent*od(jg)) |
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308 | exponential2 = exponential*exponential |
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309 | reftrans_factor = 1.0 / (k_exponent + gamma1(jg) + (k_exponent - gamma1(jg))*exponential2) |
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310 | ! Meador & Weaver (1980) Eq. 25 |
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311 | reflectance(jg) = gamma2(jg) * (1.0_jprd - exponential2) * reftrans_factor |
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312 | ! Meador & Weaver (1980) Eq. 26 |
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313 | transmittance(jg) = 2.0_jprd * k_exponent * exponential * reftrans_factor |
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314 | |
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315 | ! Emissivity of layer is one minus reflectance minus |
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316 | ! transmittance, multiply by Planck function to get emitted |
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317 | ! ousrce |
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318 | source(jg) = planck(jg) * (1.0_jprd - reflectance(jg) - transmittance(jg)) |
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319 | end do |
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320 | |
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321 | #ifdef DO_DR_HOOK_TWO_STREAM |
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322 | if (lhook) call dr_hook('radiation_two_stream:calc_reflectance_transmittance_isothermal_lw',1,hook_handle) |
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323 | #endif |
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324 | |
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325 | end subroutine calc_reflectance_transmittance_isothermal_lw |
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326 | |
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327 | |
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328 | |
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329 | !--------------------------------------------------------------------- |
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330 | ! Compute the longwave transmittance to diffuse radiation in the |
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331 | ! no-scattering case, as well as the upward flux at the top and the |
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332 | ! downward flux at the base of the layer due to emission from within |
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333 | ! the layer assuming a linear variation of Planck function within |
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334 | ! the layer. |
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335 | subroutine calc_no_scattering_transmittance_lw(ng, & |
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336 | & od, planck_top, planck_bot, transmittance, source_up, source_dn) |
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337 | |
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338 | #ifdef DO_DR_HOOK_TWO_STREAM |
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339 | use yomhook, only : lhook, dr_hook |
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340 | #endif |
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341 | |
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342 | integer, intent(in) :: ng |
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343 | |
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344 | ! Optical depth and single scattering albedo |
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345 | real(jprb), intent(in), dimension(ng) :: od |
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346 | |
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347 | ! The Planck terms (functions of temperature) at the top and |
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348 | ! bottom of the layer |
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349 | real(jprb), intent(in), dimension(ng) :: planck_top, planck_bot |
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350 | |
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351 | ! The diffuse transmittance, i.e. the fraction of diffuse |
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352 | ! radiation incident on a layer from either top or bottom that is |
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353 | ! reflected back or transmitted through |
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354 | real(jprb), intent(out), dimension(ng) :: transmittance |
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355 | |
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356 | ! The upward emission at the top of the layer and the downward |
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357 | ! emission at its base, due to emission from within the layer |
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358 | real(jprb), intent(out), dimension(ng) :: source_up, source_dn |
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359 | |
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360 | real(jprd) :: coeff, coeff_up_top, coeff_up_bot, coeff_dn_top, coeff_dn_bot !, planck_mean |
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361 | |
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362 | integer :: jg |
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363 | |
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364 | #ifdef DO_DR_HOOK_TWO_STREAM |
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365 | real(jprb) :: hook_handle |
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366 | |
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367 | if (lhook) call dr_hook('radiation_two_stream:calc_no_scattering_transmittance_lw',0,hook_handle) |
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368 | #endif |
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369 | |
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370 | ! Added for DWD (2020) |
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371 | !NEC$ shortloop |
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372 | DO jg = 1, ng |
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373 | ! Compute upward and downward emission assuming the Planck |
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374 | ! function to vary linearly with optical depth within the layer |
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375 | ! (e.g. Wiscombe , JQSRT 1976). |
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376 | if (od(jg) > 1.0e-3) then |
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377 | ! Simplified from calc_reflectance_transmittance_lw above |
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378 | coeff = LwDiffusivity*od(jg) |
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379 | transmittance(jg) = exp_fast(-coeff) |
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380 | coeff = (planck_bot(jg)-planck_top(jg)) / coeff |
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381 | coeff_up_top = coeff + planck_top(jg) |
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382 | coeff_up_bot = coeff + planck_bot(jg) |
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383 | coeff_dn_top = -coeff + planck_top(jg) |
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384 | coeff_dn_bot = -coeff + planck_bot(jg) |
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385 | source_up(jg) = coeff_up_top - transmittance(jg) * coeff_up_bot |
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386 | source_dn(jg) = coeff_dn_bot - transmittance(jg) * coeff_dn_top |
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387 | else |
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388 | ! Linear limit at low optical depth |
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389 | coeff = LwDiffusivity*od(jg) |
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390 | transmittance(jg) = 1.0_jprb - coeff |
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391 | source_up(jg) = coeff * 0.5_jprb * (planck_top(jg)+planck_bot(jg)) |
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392 | source_dn(jg) = source_up(jg) |
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393 | end if |
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394 | end do |
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395 | |
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396 | ! Method in the older IFS radiation scheme |
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397 | ! do j = 1, n |
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398 | ! coeff = od(jg) / (3.59712_jprd + od(jg)) |
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399 | ! planck_mean = 0.5_jprd * (planck_top(jg) + planck_bot(jg)) |
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400 | ! |
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401 | ! source_up(jg) = (1.0_jprd-transmittance(jg)) * (planck_mean + (planck_top(jg) - planck_mean) * coeff) |
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402 | ! source_dn(jg) = (1.0_jprd-transmittance(jg)) * (planck_mean + (planck_bot(jg) - planck_mean) * coeff) |
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403 | ! end do |
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404 | |
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405 | #ifdef DO_DR_HOOK_TWO_STREAM |
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406 | if (lhook) call dr_hook('radiation_two_stream:calc_no_scattering_transmittance_lw',1,hook_handle) |
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407 | #endif |
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408 | |
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409 | end subroutine calc_no_scattering_transmittance_lw |
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410 | |
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411 | |
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412 | !--------------------------------------------------------------------- |
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413 | ! Compute the shortwave reflectance and transmittance to diffuse |
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414 | ! radiation using the Meador & Weaver formulas, as well as the |
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415 | ! "direct" reflection and transmission, which really means the rate |
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416 | ! of transfer of direct solar radiation (into a plane perpendicular |
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417 | ! to the direct beam) into diffuse upward and downward streams at |
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418 | ! the top and bottom of the layer, respectively. Finally, |
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419 | ! trans_dir_dir is the transmittance of the atmosphere to direct |
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420 | ! radiation with no scattering. |
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421 | subroutine calc_reflectance_transmittance_sw(ng, mu0, od, ssa, & |
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422 | & gamma1, gamma2, gamma3, ref_diff, trans_diff, & |
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423 | & ref_dir, trans_dir_diff, trans_dir_dir) |
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424 | |
---|
425 | #ifdef DO_DR_HOOK_TWO_STREAM |
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426 | use yomhook, only : lhook, dr_hook |
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427 | #endif |
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428 | |
---|
429 | integer, intent(in) :: ng |
---|
430 | |
---|
431 | ! Cosine of solar zenith angle |
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432 | real(jprb), intent(in) :: mu0 |
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433 | |
---|
434 | ! Optical depth and single scattering albedo |
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435 | real(jprb), intent(in), dimension(ng) :: od, ssa |
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436 | |
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437 | ! The three transfer coefficients from the two-stream |
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438 | ! differentiatial equations (computed by calc_two_stream_gammas) |
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439 | real(jprb), intent(in), dimension(ng) :: gamma1, gamma2, gamma3 |
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440 | |
---|
441 | ! The direct reflectance and transmittance, i.e. the fraction of |
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442 | ! incoming direct solar radiation incident at the top of a layer |
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443 | ! that is either reflected back (ref_dir) or scattered but |
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444 | ! transmitted through the layer to the base (trans_dir_diff) |
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445 | real(jprb), intent(out), dimension(ng) :: ref_dir, trans_dir_diff |
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446 | |
---|
447 | ! The diffuse reflectance and transmittance, i.e. the fraction of |
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448 | ! diffuse radiation incident on a layer from either top or bottom |
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449 | ! that is reflected back or transmitted through |
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450 | real(jprb), intent(out), dimension(ng) :: ref_diff, trans_diff |
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451 | |
---|
452 | ! Transmittance of the direct been with no scattering |
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453 | real(jprb), intent(out), dimension(ng) :: trans_dir_dir |
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454 | |
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455 | real(jprd) :: gamma4, alpha1, alpha2, k_exponent, reftrans_factor |
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456 | real(jprd) :: exponential0 ! = exp(-od/mu0) |
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457 | real(jprd) :: exponential ! = exp(-k_exponent*od) |
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458 | real(jprd) :: exponential2 ! = exp(-2*k_exponent*od) |
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459 | real(jprd) :: k_mu0, k_gamma3, k_gamma4 |
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460 | real(jprd) :: k_2_exponential, od_over_mu0 |
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461 | integer :: jg |
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462 | |
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463 | ! Local value of cosine of solar zenith angle, in case it needs to be |
---|
464 | ! tweaked to avoid near division by zero. This is intentionally in working |
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465 | ! precision (jprb) rather than fixing at double precision (jprd). |
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466 | real(jprb) :: mu0_local |
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467 | |
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468 | #ifdef DO_DR_HOOK_TWO_STREAM |
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469 | real(jprb) :: hook_handle |
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470 | |
---|
471 | if (lhook) call dr_hook('radiation_two_stream:calc_reflectance_transmittance_sw',0,hook_handle) |
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472 | #endif |
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473 | |
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474 | ! Added for DWD (2020) |
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475 | !NEC$ shortloop |
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476 | DO jg = 1, ng |
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477 | |
---|
478 | gamma4 = 1.0_jprd - gamma3(jg) |
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479 | alpha1 = gamma1(jg)*gamma4 + gamma2(jg)*gamma3(jg) ! Eq. 16 |
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480 | alpha2 = gamma1(jg)*gamma3(jg) + gamma2(jg)*gamma4 ! Eq. 17 |
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481 | |
---|
482 | k_exponent = sqrt(max((gamma1(jg) - gamma2(jg)) * (gamma1(jg) + gamma2(jg)), & |
---|
483 | & 1.0e-12_jprd)) ! Eq 18 |
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484 | |
---|
485 | ! We had a rare crash where k*mu0 was within around 1e-13 of 1, |
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486 | ! leading to ref_dir and trans_dir_diff being well outside the range |
---|
487 | ! 0-1. The following approach is appropriate when k_exponent is double |
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488 | ! precision and mu0_local is single precision, although work is needed |
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489 | ! to make this entire routine secure in single precision. |
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490 | mu0_local = mu0 |
---|
491 | if (abs(1.0_jprd - k_exponent*mu0) < 1000.0_jprd * epsilon(1.0_jprd)) then |
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492 | mu0_local = mu0 * (1.0_jprb - 10.0_jprb*epsilon(1.0_jprb)) |
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493 | end if |
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494 | |
---|
495 | od_over_mu0 = max(od(jg) / mu0_local, 0.0_jprd) |
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496 | |
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497 | ! Note that if the minimum value is reduced (e.g. to 1.0e-24) |
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498 | ! then noise starts to appear as a function of solar zenith |
---|
499 | ! angle |
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500 | k_mu0 = k_exponent*mu0_local |
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501 | k_gamma3 = k_exponent*gamma3(jg) |
---|
502 | k_gamma4 = k_exponent*gamma4 |
---|
503 | ! Check for mu0 <= 0! |
---|
504 | exponential0 = exp_fast(-od_over_mu0) |
---|
505 | trans_dir_dir(jg) = exponential0 |
---|
506 | exponential = exp_fast(-k_exponent*od(jg)) |
---|
507 | |
---|
508 | exponential2 = exponential*exponential |
---|
509 | k_2_exponential = 2.0_jprd * k_exponent * exponential |
---|
510 | |
---|
511 | reftrans_factor = 1.0_jprd / (k_exponent + gamma1(jg) + (k_exponent - gamma1(jg))*exponential2) |
---|
512 | |
---|
513 | ! Meador & Weaver (1980) Eq. 25 |
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514 | ref_diff(jg) = gamma2(jg) * (1.0_jprd - exponential2) * reftrans_factor |
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515 | |
---|
516 | ! Meador & Weaver (1980) Eq. 26 |
---|
517 | trans_diff(jg) = k_2_exponential * reftrans_factor |
---|
518 | |
---|
519 | ! Here we need mu0 even though it wasn't in Meador and Weaver |
---|
520 | ! because we are assuming the incoming direct flux is defined |
---|
521 | ! to be the flux into a plane perpendicular to the direction of |
---|
522 | ! the sun, not into a horizontal plane |
---|
523 | reftrans_factor = mu0_local * ssa(jg) * reftrans_factor / (1.0_jprd - k_mu0*k_mu0) |
---|
524 | |
---|
525 | ! Meador & Weaver (1980) Eq. 14, multiplying top & bottom by |
---|
526 | ! exp(-k_exponent*od) in case of very high optical depths |
---|
527 | ref_dir(jg) = reftrans_factor & |
---|
528 | & * ( (1.0_jprd - k_mu0) * (alpha2 + k_gamma3) & |
---|
529 | & -(1.0_jprd + k_mu0) * (alpha2 - k_gamma3)*exponential2 & |
---|
530 | & -k_2_exponential*(gamma3(jg) - alpha2*mu0_local)*exponential0) |
---|
531 | |
---|
532 | ! Meador & Weaver (1980) Eq. 15, multiplying top & bottom by |
---|
533 | ! exp(-k_exponent*od), minus the 1*exp(-od/mu0) term representing direct |
---|
534 | ! unscattered transmittance. |
---|
535 | trans_dir_diff(jg) = reftrans_factor * ( k_2_exponential*(gamma4 + alpha1*mu0_local) & |
---|
536 | & - exponential0 & |
---|
537 | & * ( (1.0_jprd + k_mu0) * (alpha1 + k_gamma4) & |
---|
538 | & -(1.0_jprd - k_mu0) * (alpha1 - k_gamma4) * exponential2) ) |
---|
539 | |
---|
540 | ! Final check that ref_dir + trans_dir_diff <= 1 |
---|
541 | ref_dir(jg) = max(0.0_jprb, min(ref_dir(jg), 1.0_jprb)) |
---|
542 | trans_dir_diff(jg) = max(0.0_jprb, min(trans_dir_diff(jg), 1.0_jprb-ref_dir(jg))) |
---|
543 | |
---|
544 | end do |
---|
545 | |
---|
546 | #ifdef DO_DR_HOOK_TWO_STREAM |
---|
547 | if (lhook) call dr_hook('radiation_two_stream:calc_reflectance_transmittance_sw',1,hook_handle) |
---|
548 | #endif |
---|
549 | |
---|
550 | end subroutine calc_reflectance_transmittance_sw |
---|
551 | |
---|
552 | !--------------------------------------------------------------------- |
---|
553 | ! As above but with height as a vertical coordinate rather than |
---|
554 | ! optical depth |
---|
555 | subroutine calc_reflectance_transmittance_z_sw(ng, mu0, depth, & |
---|
556 | & gamma0, gamma1, gamma2, gamma3, gamma4, & |
---|
557 | & ref_diff, trans_diff, ref_dir, trans_dir_diff, trans_dir_dir) |
---|
558 | |
---|
559 | #ifdef DO_DR_HOOK_TWO_STREAM |
---|
560 | use yomhook, only : lhook, dr_hook |
---|
561 | #endif |
---|
562 | |
---|
563 | integer, intent(in) :: ng |
---|
564 | |
---|
565 | ! Cosine of solar zenith angle |
---|
566 | real(jprb), intent(in) :: mu0 |
---|
567 | |
---|
568 | ! Layer depth |
---|
569 | real(jprb), intent(in) :: depth |
---|
570 | |
---|
571 | ! The four transfer coefficients from the two-stream |
---|
572 | ! differentiatial equations |
---|
573 | real(jprb), intent(in), dimension(ng) :: gamma1, gamma2, gamma3, gamma4 |
---|
574 | |
---|
575 | ! An additional coefficient for direct unscattered flux "Fdir" |
---|
576 | ! such that dFdir/dz = -gamma0*Fdir |
---|
577 | real(jprb), intent(in), dimension(ng) :: gamma0 |
---|
578 | |
---|
579 | ! The direct reflectance and transmittance, i.e. the fraction of |
---|
580 | ! incoming direct solar radiation incident at the top of a layer |
---|
581 | ! that is either reflected back (ref_dir) or scattered but |
---|
582 | ! transmitted through the layer to the base (trans_dir_diff) |
---|
583 | real(jprb), intent(out), dimension(ng) :: ref_dir, trans_dir_diff |
---|
584 | |
---|
585 | ! The diffuse reflectance and transmittance, i.e. the fraction of |
---|
586 | ! diffuse radiation incident on a layer from either top or bottom |
---|
587 | ! that is reflected back or transmitted through |
---|
588 | real(jprb), intent(out), dimension(ng) :: ref_diff, trans_diff |
---|
589 | |
---|
590 | ! Transmittance of the direct been with no scattering |
---|
591 | real(jprb), intent(out), dimension(ng) :: trans_dir_dir |
---|
592 | |
---|
593 | real(jprd) :: alpha1, alpha2, k_exponent, reftrans_factor |
---|
594 | real(jprd) :: exponential0 ! = exp(-od/mu0) |
---|
595 | real(jprd) :: exponential ! = exp(-k_exponent*od) |
---|
596 | real(jprd) :: exponential2 ! = exp(-2*k_exponent*od) |
---|
597 | real(jprd) :: k_mu0, k_gamma3, k_gamma4 |
---|
598 | real(jprd) :: k_2_exponential, od_over_mu0 |
---|
599 | integer :: jg |
---|
600 | |
---|
601 | #ifdef DO_DR_HOOK_TWO_STREAM |
---|
602 | real(jprb) :: hook_handle |
---|
603 | |
---|
604 | if (lhook) call dr_hook('radiation_two_stream:calc_reflectance_transmittance_z_sw',0,hook_handle) |
---|
605 | #endif |
---|
606 | |
---|
607 | ! Added for DWD (2020) |
---|
608 | !NEC$ shortloop |
---|
609 | DO jg = 1, ng |
---|
610 | od_over_mu0 = max(gamma0(jg) * depth, 0.0_jprd) |
---|
611 | ! In the IFS this appears to be faster without testing the value |
---|
612 | ! of od_over_mu0: |
---|
613 | if (.true.) then |
---|
614 | ! if (od_over_mu0 > 1.0e-6_jprd) then |
---|
615 | alpha1 = gamma1(jg)*gamma4(jg) + gamma2(jg)*gamma3(jg) ! Eq. 16 |
---|
616 | alpha2 = gamma1(jg)*gamma3(jg) + gamma2(jg)*gamma4(jg) ! Eq. 17 |
---|
617 | |
---|
618 | ! Note that if the minimum value is reduced (e.g. to 1.0e-24) |
---|
619 | ! then noise starts to appear as a function of solar zenith |
---|
620 | ! angle |
---|
621 | k_exponent = sqrt(max((gamma1(jg) - gamma2(jg)) * (gamma1(jg) + gamma2(jg)), & |
---|
622 | & 1.0e-12_jprd)) ! Eq 18 |
---|
623 | k_mu0 = k_exponent*mu0 |
---|
624 | k_gamma3 = k_exponent*gamma3(jg) |
---|
625 | k_gamma4 = k_exponent*gamma4(jg) |
---|
626 | ! Check for mu0 <= 0! |
---|
627 | exponential0 = exp_fast(-od_over_mu0) |
---|
628 | trans_dir_dir(jg) = exponential0 |
---|
629 | exponential = exp_fast(-k_exponent*depth) |
---|
630 | |
---|
631 | exponential2 = exponential*exponential |
---|
632 | k_2_exponential = 2.0_jprd * k_exponent * exponential |
---|
633 | |
---|
634 | if (k_mu0 == 1.0_jprd) then |
---|
635 | k_mu0 = 1.0_jprd - 10.0_jprd*epsilon(1.0_jprd) |
---|
636 | end if |
---|
637 | |
---|
638 | reftrans_factor = 1.0_jprd / (k_exponent + gamma1(jg) + (k_exponent - gamma1(jg))*exponential2) |
---|
639 | |
---|
640 | ! Meador & Weaver (1980) Eq. 25 |
---|
641 | ref_diff(jg) = gamma2(jg) * (1.0_jprd - exponential2) * reftrans_factor |
---|
642 | |
---|
643 | ! Meador & Weaver (1980) Eq. 26 |
---|
644 | trans_diff(jg) = k_2_exponential * reftrans_factor |
---|
645 | |
---|
646 | ! Here we need mu0 even though it wasn't in Meador and Weaver |
---|
647 | ! because we are assuming the incoming direct flux is defined |
---|
648 | ! to be the flux into a plane perpendicular to the direction of |
---|
649 | ! the sun, not into a horizontal plane |
---|
650 | reftrans_factor = mu0 * reftrans_factor / (1.0_jprd - k_mu0*k_mu0) |
---|
651 | |
---|
652 | ! Meador & Weaver (1980) Eq. 14, multiplying top & bottom by |
---|
653 | ! exp(-k_exponent*od) in case of very high optical depths |
---|
654 | ref_dir(jg) = reftrans_factor & |
---|
655 | & * ( (1.0_jprd - k_mu0) * (alpha2 + k_gamma3) & |
---|
656 | & -(1.0_jprd + k_mu0) * (alpha2 - k_gamma3)*exponential2 & |
---|
657 | & -k_2_exponential*(gamma3(jg) - alpha2*mu0)*exponential0) |
---|
658 | |
---|
659 | ! Meador & Weaver (1980) Eq. 15, multiplying top & bottom by |
---|
660 | ! exp(-k_exponent*od), minus the 1*exp(-od/mu0) term representing direct |
---|
661 | ! unscattered transmittance. |
---|
662 | trans_dir_diff(jg) = reftrans_factor * ( k_2_exponential*(gamma4(jg) + alpha1*mu0) & |
---|
663 | & - exponential0 & |
---|
664 | & * ( (1.0_jprd + k_mu0) * (alpha1 + k_gamma4) & |
---|
665 | & -(1.0_jprd - k_mu0) * (alpha1 - k_gamma4) * exponential2) ) |
---|
666 | |
---|
667 | else |
---|
668 | ! Low optical-depth limit; see equations 19, 20 and 27 from |
---|
669 | ! Meador & Weaver (1980) |
---|
670 | trans_diff(jg) = 1.0_jprb - gamma1(jg) * depth |
---|
671 | ref_diff(jg) = gamma2(jg) * depth |
---|
672 | trans_dir_diff(jg) = (1.0_jprb - gamma3(jg)) * depth |
---|
673 | ref_dir(jg) = gamma3(jg) * depth |
---|
674 | trans_dir_dir(jg) = 1.0_jprd - od_over_mu0 |
---|
675 | end if |
---|
676 | end do |
---|
677 | |
---|
678 | #ifdef DO_DR_HOOK_TWO_STREAM |
---|
679 | if (lhook) call dr_hook('radiation_two_stream:calc_reflectance_transmittance_z_sw',1,hook_handle) |
---|
680 | #endif |
---|
681 | |
---|
682 | end subroutine calc_reflectance_transmittance_z_sw |
---|
683 | |
---|
684 | |
---|
685 | !--------------------------------------------------------------------- |
---|
686 | ! Compute the fraction of shortwave transmitted diffuse radiation |
---|
687 | ! that is scattered during its transmission, used to compute |
---|
688 | ! entrapment in SPARTACUS |
---|
689 | subroutine calc_frac_scattered_diffuse_sw(ng, od, & |
---|
690 | & gamma1, gamma2, frac_scat_diffuse) |
---|
691 | |
---|
692 | #ifdef DO_DR_HOOK_TWO_STREAM |
---|
693 | use yomhook, only : lhook, dr_hook |
---|
694 | #endif |
---|
695 | |
---|
696 | integer, intent(in) :: ng |
---|
697 | |
---|
698 | ! Optical depth |
---|
699 | real(jprb), intent(in), dimension(ng) :: od |
---|
700 | |
---|
701 | ! The first two transfer coefficients from the two-stream |
---|
702 | ! differentiatial equations (computed by calc_two_stream_gammas) |
---|
703 | real(jprb), intent(in), dimension(ng) :: gamma1, gamma2 |
---|
704 | |
---|
705 | ! The fraction of shortwave transmitted diffuse radiation that is |
---|
706 | ! scattered during its transmission |
---|
707 | real(jprb), intent(out), dimension(ng) :: frac_scat_diffuse |
---|
708 | |
---|
709 | real(jprd) :: k_exponent, reftrans_factor |
---|
710 | real(jprd) :: exponential ! = exp(-k_exponent*od) |
---|
711 | real(jprd) :: exponential2 ! = exp(-2*k_exponent*od) |
---|
712 | real(jprd) :: k_2_exponential |
---|
713 | integer :: jg |
---|
714 | |
---|
715 | #ifdef DO_DR_HOOK_TWO_STREAM |
---|
716 | real(jprb) :: hook_handle |
---|
717 | |
---|
718 | if (lhook) call dr_hook('radiation_two_stream:calc_frac_scattered_diffuse_sw',0,hook_handle) |
---|
719 | #endif |
---|
720 | |
---|
721 | ! Added for DWD (2020) |
---|
722 | !NEC$ shortloop |
---|
723 | DO jg = 1, ng |
---|
724 | ! Note that if the minimum value is reduced (e.g. to 1.0e-24) |
---|
725 | ! then noise starts to appear as a function of solar zenith |
---|
726 | ! angle |
---|
727 | k_exponent = sqrt(max((gamma1(jg) - gamma2(jg)) * (gamma1(jg) + gamma2(jg)), & |
---|
728 | & 1.0e-12_jprd)) ! Eq 18 |
---|
729 | exponential = exp_fast(-k_exponent*od(jg)) |
---|
730 | exponential2 = exponential*exponential |
---|
731 | k_2_exponential = 2.0_jprd * k_exponent * exponential |
---|
732 | |
---|
733 | reftrans_factor = 1.0_jprd / (k_exponent + gamma1(jg) + (k_exponent - gamma1(jg))*exponential2) |
---|
734 | |
---|
735 | ! Meador & Weaver (1980) Eq. 26. |
---|
736 | ! Until 1.1.8, used LwDiffusivity instead of 2.0, although the |
---|
737 | ! effect is very small |
---|
738 | ! frac_scat_diffuse(jg) = 1.0_jprb - min(1.0_jprb,exp_fast(-LwDiffusivity*od(jg)) & |
---|
739 | ! & / max(1.0e-8_jprb, k_2_exponential * reftrans_factor)) |
---|
740 | frac_scat_diffuse(jg) = 1.0_jprb & |
---|
741 | & - min(1.0_jprb,exp_fast(-2.0_jprb*od(jg)) & |
---|
742 | & / max(1.0e-8_jprb, k_2_exponential * reftrans_factor)) |
---|
743 | end do |
---|
744 | |
---|
745 | #ifdef DO_DR_HOOK_TWO_STREAM |
---|
746 | if (lhook) call dr_hook('radiation_two_stream:calc_frac_scattered_diffuse_sw',1,hook_handle) |
---|
747 | #endif |
---|
748 | |
---|
749 | end subroutine calc_frac_scattered_diffuse_sw |
---|
750 | |
---|
751 | end module radiation_two_stream |
---|