1 | !> @file lpm_advec.f90 |
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2 | !------------------------------------------------------------------------------! |
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3 | ! This file is part of PALM. |
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4 | ! |
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5 | ! PALM is free software: you can redistribute it and/or modify it under the |
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6 | ! terms of the GNU General Public License as published by the Free Software |
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7 | ! Foundation, either version 3 of the License, or (at your option) any later |
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8 | ! version. |
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9 | ! |
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10 | ! PALM is distributed in the hope that it will be useful, but WITHOUT ANY |
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11 | ! WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR |
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12 | ! A PARTICULAR PURPOSE. See the GNU General Public License for more details. |
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13 | ! |
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14 | ! You should have received a copy of the GNU General Public License along with |
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15 | ! PALM. If not, see <http://www.gnu.org/licenses/>. |
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16 | ! |
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17 | ! Copyright 1997-2016 Leibniz Universitaet Hannover |
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18 | !------------------------------------------------------------------------------! |
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19 | ! |
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20 | ! Current revisions: |
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21 | ! ------------------ |
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22 | ! |
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23 | ! |
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24 | ! Former revisions: |
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25 | ! ----------------- |
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26 | ! $Id: lpm_advec.f90 2001 2016-08-20 18:41:22Z gronemeier $ |
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27 | ! |
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28 | ! 2000 2016-08-20 18:09:15Z knoop |
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29 | ! Forced header and separation lines into 80 columns |
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30 | ! |
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31 | ! 1936 2016-06-13 13:37:44Z suehring |
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32 | ! Formatting adjustments |
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33 | ! |
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34 | ! 1929 2016-06-09 16:25:25Z suehring |
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35 | ! Put stochastic equation in an extra subroutine. |
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36 | ! Set flag for stochastic equation to communicate whether a particle is near |
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37 | ! topography. This case, memory and drift term are disabled in the Weil equation. |
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38 | ! |
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39 | ! Enable vertical logarithmic interpolation also above topography. This case, |
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40 | ! set a lower limit for the friction velocity, as it can become very small |
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41 | ! in narrow street canyons, leading to too large particle speeds. |
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42 | ! |
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43 | ! 1888 2016-04-21 12:20:49Z suehring |
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44 | ! Bugfix concerning logarithmic interpolation of particle speed |
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45 | ! |
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46 | ! 1822 2016-04-07 07:49:42Z hoffmann |
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47 | ! Random velocity fluctuations for particles added. Terminal fall velocity |
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48 | ! for droplets is calculated from a parameterization (which is better than |
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49 | ! the previous, physically correct calculation, which demands a very short |
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50 | ! time step that is not used in the model). |
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51 | ! |
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52 | ! Unused variables deleted. |
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53 | ! |
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54 | ! 1691 2015-10-26 16:17:44Z maronga |
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55 | ! Renamed prandtl_layer to constant_flux_layer. |
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56 | ! |
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57 | ! 1685 2015-10-08 07:32:13Z raasch |
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58 | ! TKE check for negative values (so far, only zero value was checked) |
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59 | ! offset_ocean_nzt_m1 removed |
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60 | ! |
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61 | ! 1682 2015-10-07 23:56:08Z knoop |
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62 | ! Code annotations made doxygen readable |
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63 | ! |
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64 | ! 1583 2015-04-15 12:16:27Z suehring |
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65 | ! Bugfix: particle advection within Prandtl-layer in case of Galilei |
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66 | ! transformation. |
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67 | ! |
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68 | ! 1369 2014-04-24 05:57:38Z raasch |
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69 | ! usage of module interfaces removed |
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70 | ! |
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71 | ! 1359 2014-04-11 17:15:14Z hoffmann |
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72 | ! New particle structure integrated. |
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73 | ! Kind definition added to all floating point numbers. |
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74 | ! |
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75 | ! 1322 2014-03-20 16:38:49Z raasch |
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76 | ! REAL constants defined as wp_kind |
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77 | ! |
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78 | ! 1320 2014-03-20 08:40:49Z raasch |
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79 | ! ONLY-attribute added to USE-statements, |
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80 | ! kind-parameters added to all INTEGER and REAL declaration statements, |
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81 | ! kinds are defined in new module kinds, |
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82 | ! revision history before 2012 removed, |
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83 | ! comment fields (!:) to be used for variable explanations added to |
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84 | ! all variable declaration statements |
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85 | ! |
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86 | ! 1314 2014-03-14 18:25:17Z suehring |
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87 | ! Vertical logarithmic interpolation of horizontal particle speed for particles |
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88 | ! between roughness height and first vertical grid level. |
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89 | ! |
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90 | ! 1036 2012-10-22 13:43:42Z raasch |
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91 | ! code put under GPL (PALM 3.9) |
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92 | ! |
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93 | ! 849 2012-03-15 10:35:09Z raasch |
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94 | ! initial revision (former part of advec_particles) |
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95 | ! |
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96 | ! |
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97 | ! Description: |
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98 | ! ------------ |
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99 | !> Calculation of new particle positions due to advection using a simple Euler |
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100 | !> scheme. Particles may feel inertia effects. SGS transport can be included |
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101 | !> using the stochastic model of Weil et al. (2004, JAS, 61, 2877-2887). |
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102 | !------------------------------------------------------------------------------! |
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103 | SUBROUTINE lpm_advec (ip,jp,kp) |
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104 | |
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105 | |
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106 | USE arrays_3d, & |
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107 | ONLY: de_dx, de_dy, de_dz, diss, e, km, u, us, usws, v, vsws, w, zu, zw |
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108 | |
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109 | USE cpulog |
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110 | |
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111 | USE pegrid |
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112 | |
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113 | USE control_parameters, & |
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114 | ONLY: atmos_ocean_sign, cloud_droplets, constant_flux_layer, dt_3d, & |
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115 | dt_3d_reached_l, dz, g, kappa, topography, u_gtrans, v_gtrans |
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116 | |
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117 | USE grid_variables, & |
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118 | ONLY: ddx, dx, ddy, dy |
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119 | |
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120 | USE indices, & |
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121 | ONLY: nzb, nzb_s_inner, nzt |
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122 | |
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123 | USE kinds |
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124 | |
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125 | USE particle_attributes, & |
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126 | ONLY: block_offset, c_0, dt_min_part, grid_particles, & |
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127 | iran_part, log_z_z0, number_of_particles, number_of_sublayers, & |
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128 | particles, particle_groups, offset_ocean_nzt, sgs_wf_part, & |
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129 | use_sgs_for_particles, vertical_particle_advection, z0_av_global |
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130 | |
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131 | USE statistics, & |
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132 | ONLY: hom |
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133 | |
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134 | IMPLICIT NONE |
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135 | |
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136 | INTEGER(iwp) :: agp !< loop variable |
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137 | INTEGER(iwp) :: gp_outside_of_building(1:8) !< number of grid points used for particle interpolation in case of topography |
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138 | INTEGER(iwp) :: i !< index variable along x |
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139 | INTEGER(iwp) :: ip !< index variable along x |
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140 | INTEGER(iwp) :: ilog !< index variable along x |
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141 | INTEGER(iwp) :: j !< index variable along y |
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142 | INTEGER(iwp) :: jp !< index variable along y |
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143 | INTEGER(iwp) :: jlog !< index variable along y |
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144 | INTEGER(iwp) :: k !< index variable along z |
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145 | INTEGER(iwp) :: kp !< index variable along z |
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146 | INTEGER(iwp) :: kw !< index variable along z |
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147 | INTEGER(iwp) :: n !< loop variable over all particles in a grid box |
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148 | INTEGER(iwp) :: nb !< block number particles are sorted in |
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149 | INTEGER(iwp) :: num_gp !< number of adjacent grid points inside topography |
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150 | |
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151 | INTEGER(iwp), DIMENSION(0:7) :: start_index !< start particle index for current block |
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152 | INTEGER(iwp), DIMENSION(0:7) :: end_index !< start particle index for current block |
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153 | |
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154 | REAL(wp) :: aa !< dummy argument for horizontal particle interpolation |
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155 | REAL(wp) :: bb !< dummy argument for horizontal particle interpolation |
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156 | REAL(wp) :: cc !< dummy argument for horizontal particle interpolation |
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157 | REAL(wp) :: d_sum !< dummy argument for horizontal particle interpolation in case of topography |
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158 | REAL(wp) :: d_z_p_z0 !< inverse of interpolation length for logarithmic interpolation |
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159 | REAL(wp) :: dd !< dummy argument for horizontal particle interpolation |
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160 | REAL(wp) :: de_dx_int_l !< x/y-interpolated TKE gradient (x) at particle position at lower vertical level |
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161 | REAL(wp) :: de_dx_int_u !< x/y-interpolated TKE gradient (x) at particle position at upper vertical level |
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162 | REAL(wp) :: de_dy_int_l !< x/y-interpolated TKE gradient (y) at particle position at lower vertical level |
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163 | REAL(wp) :: de_dy_int_u !< x/y-interpolated TKE gradient (y) at particle position at upper vertical level |
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164 | REAL(wp) :: de_dt !< temporal derivative of TKE experienced by the particle |
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165 | REAL(wp) :: de_dt_min !< lower level for temporal TKE derivative |
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166 | REAL(wp) :: de_dz_int_l !< x/y-interpolated TKE gradient (z) at particle position at lower vertical level |
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167 | REAL(wp) :: de_dz_int_u !< x/y-interpolated TKE gradient (z) at particle position at upper vertical level |
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168 | REAL(wp) :: diameter !< diamter of droplet |
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169 | REAL(wp) :: diss_int_l !< x/y-interpolated dissipation at particle position at lower vertical level |
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170 | REAL(wp) :: diss_int_u !< x/y-interpolated dissipation at particle position at upper vertical level |
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171 | REAL(wp) :: dt_gap !< remaining time until particle time integration reaches LES time |
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172 | REAL(wp) :: dt_particle_m !< previous particle time step |
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173 | REAL(wp) :: e_int_l !< x/y-interpolated TKE at particle position at lower vertical level |
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174 | REAL(wp) :: e_int_u !< x/y-interpolated TKE at particle position at upper vertical level |
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175 | REAL(wp) :: e_mean_int !< horizontal mean TKE at particle height |
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176 | REAL(wp) :: exp_arg !< |
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177 | REAL(wp) :: exp_term !< |
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178 | REAL(wp) :: gg !< dummy argument for horizontal particle interpolation |
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179 | REAL(wp) :: height_p !< dummy argument for logarithmic interpolation |
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180 | REAL(wp) :: lagr_timescale !< Lagrangian timescale |
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181 | REAL(wp) :: location(1:30,1:3) !< wall locations |
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182 | REAL(wp) :: log_z_z0_int !< logarithmus used for surface_layer interpolation |
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183 | REAL(wp) :: random_gauss !< |
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184 | REAL(wp) :: RL !< Lagrangian autocorrelation coefficient |
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185 | REAL(wp) :: rg1 !< Gaussian distributed random number |
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186 | REAL(wp) :: rg2 !< Gaussian distributed random number |
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187 | REAL(wp) :: rg3 !< Gaussian distributed random number |
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188 | REAL(wp) :: sigma !< velocity standard deviation |
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189 | REAL(wp) :: u_int_l !< x/y-interpolated u-component at particle position at lower vertical level |
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190 | REAL(wp) :: u_int_u !< x/y-interpolated u-component at particle position at upper vertical level |
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191 | REAL(wp) :: us_int !< friction velocity at particle grid box |
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192 | REAL(wp) :: v_int_l !< x/y-interpolated v-component at particle position at lower vertical level |
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193 | REAL(wp) :: v_int_u !< x/y-interpolated v-component at particle position at upper vertical level |
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194 | REAL(wp) :: vv_int !< |
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195 | REAL(wp) :: w_int_l !< x/y-interpolated w-component at particle position at lower vertical level |
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196 | REAL(wp) :: w_int_u !< x/y-interpolated w-component at particle position at upper vertical level |
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197 | REAL(wp) :: w_s !< terminal velocity of droplets |
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198 | REAL(wp) :: x !< dummy argument for horizontal particle interpolation |
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199 | REAL(wp) :: y !< dummy argument for horizontal particle interpolation |
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200 | REAL(wp) :: z_p !< surface layer height (0.5 dz) |
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201 | |
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202 | REAL(wp), PARAMETER :: a_rog = 9.65_wp !< parameter for fall velocity |
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203 | REAL(wp), PARAMETER :: b_rog = 10.43_wp !< parameter for fall velocity |
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204 | REAL(wp), PARAMETER :: c_rog = 0.6_wp !< parameter for fall velocity |
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205 | REAL(wp), PARAMETER :: k_cap_rog = 4.0_wp !< parameter for fall velocity |
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206 | REAL(wp), PARAMETER :: k_low_rog = 12.0_wp !< parameter for fall velocity |
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207 | REAL(wp), PARAMETER :: d0_rog = 0.745_wp !< separation diameter |
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208 | |
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209 | REAL(wp), DIMENSION(1:30) :: d_gp_pl !< dummy argument for particle interpolation scheme in case of topography |
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210 | REAL(wp), DIMENSION(1:30) :: de_dxi !< horizontal TKE gradient along x at adjacent wall |
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211 | REAL(wp), DIMENSION(1:30) :: de_dyi !< horizontal TKE gradient along y at adjacent wall |
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212 | REAL(wp), DIMENSION(1:30) :: de_dzi !< horizontal TKE gradient along z at adjacent wall |
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213 | REAL(wp), DIMENSION(1:30) :: dissi !< dissipation at adjacent wall |
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214 | REAL(wp), DIMENSION(1:30) :: ei !< TKE at adjacent wall |
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215 | |
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216 | REAL(wp), DIMENSION(number_of_particles) :: term_1_2 !< flag to communicate whether a particle is near topography or not |
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217 | REAL(wp), DIMENSION(number_of_particles) :: dens_ratio !< |
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218 | REAL(wp), DIMENSION(number_of_particles) :: de_dx_int !< horizontal TKE gradient along x at particle position |
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219 | REAL(wp), DIMENSION(number_of_particles) :: de_dy_int !< horizontal TKE gradient along y at particle position |
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220 | REAL(wp), DIMENSION(number_of_particles) :: de_dz_int !< horizontal TKE gradient along z at particle position |
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221 | REAL(wp), DIMENSION(number_of_particles) :: diss_int !< dissipation at particle position |
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222 | REAL(wp), DIMENSION(number_of_particles) :: dt_particle !< particle time step |
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223 | REAL(wp), DIMENSION(number_of_particles) :: e_int !< TKE at particle position |
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224 | REAL(wp), DIMENSION(number_of_particles) :: fs_int !< weighting factor for subgrid-scale particle speed |
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225 | REAL(wp), DIMENSION(number_of_particles) :: u_int !< u-component of particle speed |
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226 | REAL(wp), DIMENSION(number_of_particles) :: v_int !< v-component of particle speed |
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227 | REAL(wp), DIMENSION(number_of_particles) :: w_int !< w-component of particle speed |
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228 | REAL(wp), DIMENSION(number_of_particles) :: xv !< x-position |
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229 | REAL(wp), DIMENSION(number_of_particles) :: yv !< y-position |
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230 | REAL(wp), DIMENSION(number_of_particles) :: zv !< z-position |
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231 | |
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232 | REAL(wp), DIMENSION(number_of_particles, 3) :: rg !< vector of Gaussian distributed random numbers |
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233 | |
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234 | CALL cpu_log( log_point_s(44), 'lpm_advec', 'continue' ) |
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235 | |
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236 | ! |
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237 | !-- Determine height of Prandtl layer and distance between Prandtl-layer |
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238 | !-- height and horizontal mean roughness height, which are required for |
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239 | !-- vertical logarithmic interpolation of horizontal particle speeds |
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240 | !-- (for particles below first vertical grid level). |
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241 | z_p = zu(nzb+1) - zw(nzb) |
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242 | d_z_p_z0 = 1.0_wp / ( z_p - z0_av_global ) |
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243 | |
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244 | start_index = grid_particles(kp,jp,ip)%start_index |
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245 | end_index = grid_particles(kp,jp,ip)%end_index |
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246 | |
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247 | xv = particles(1:number_of_particles)%x |
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248 | yv = particles(1:number_of_particles)%y |
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249 | zv = particles(1:number_of_particles)%z |
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250 | |
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251 | DO nb = 0, 7 |
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252 | |
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253 | i = ip |
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254 | j = jp + block_offset(nb)%j_off |
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255 | k = kp + block_offset(nb)%k_off |
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256 | |
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257 | |
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258 | ! |
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259 | !-- Interpolate u velocity-component |
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260 | DO n = start_index(nb), end_index(nb) |
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261 | ! |
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262 | !-- Interpolation of the u velocity component onto particle position. |
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263 | !-- Particles are interpolation bi-linearly in the horizontal and a |
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264 | !-- linearly in the vertical. An exception is made for particles below |
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265 | !-- the first vertical grid level in case of a prandtl layer. In this |
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266 | !-- case the horizontal particle velocity components are determined using |
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267 | !-- Monin-Obukhov relations (if branch). |
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268 | !-- First, check if particle is located below first vertical grid level |
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269 | !-- (Prandtl-layer height) |
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270 | ilog = ( particles(n)%x + 0.5_wp * dx ) * ddx |
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271 | jlog = ( particles(n)%y + 0.5_wp * dy ) * ddy |
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272 | |
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273 | IF ( constant_flux_layer .AND. & |
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274 | zv(n) - zw(nzb_s_inner(jlog,ilog)) < z_p ) THEN |
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275 | ! |
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276 | !-- Resolved-scale horizontal particle velocity is zero below z0. |
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277 | IF ( zv(n) - zw(nzb_s_inner(jlog,ilog)) < z0_av_global ) THEN |
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278 | u_int(n) = 0.0_wp |
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279 | ELSE |
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280 | ! |
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281 | !-- Determine the sublayer. Further used as index. |
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282 | height_p = ( zv(n) - zw(nzb_s_inner(jlog,ilog)) - z0_av_global ) & |
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283 | * REAL( number_of_sublayers, KIND=wp ) & |
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284 | * d_z_p_z0 |
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285 | ! |
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286 | !-- Calculate LOG(z/z0) for exact particle height. Therefore, |
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287 | !-- interpolate linearly between precalculated logarithm. |
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288 | log_z_z0_int = log_z_z0(INT(height_p)) & |
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289 | + ( height_p - INT(height_p) ) & |
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290 | * ( log_z_z0(INT(height_p)+1) & |
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291 | - log_z_z0(INT(height_p)) & |
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292 | ) |
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293 | ! |
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294 | !-- Limit friction velocity. In narrow canyons or holes the |
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295 | !-- friction velocity can become very small, resulting in a too |
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296 | !-- large particle speed. |
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297 | us_int = MAX( 0.5_wp * ( us(jlog,ilog) + us(jlog,ilog-1) ), & |
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298 | 0.01_wp ) |
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299 | ! |
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300 | !-- Neutral solution is applied for all situations, e.g. also for |
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301 | !-- unstable and stable situations. Even though this is not exact |
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302 | !-- this saves a lot of CPU time since several calls of intrinsic |
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303 | !-- FORTRAN procedures (LOG, ATAN) are avoided, This is justified |
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304 | !-- as sensitivity studies revealed no significant effect of |
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305 | !-- using the neutral solution also for un/stable situations. |
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306 | u_int(n) = -usws(jlog,ilog) / ( us_int * kappa + 1E-10_wp ) & |
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307 | * log_z_z0_int - u_gtrans |
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308 | |
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309 | ENDIF |
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310 | ! |
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311 | !-- Particle above the first grid level. Bi-linear interpolation in the |
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312 | !-- horizontal and linear interpolation in the vertical direction. |
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313 | ELSE |
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314 | |
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315 | x = xv(n) + ( 0.5_wp - i ) * dx |
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316 | y = yv(n) - j * dy |
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317 | aa = x**2 + y**2 |
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318 | bb = ( dx - x )**2 + y**2 |
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319 | cc = x**2 + ( dy - y )**2 |
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320 | dd = ( dx - x )**2 + ( dy - y )**2 |
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321 | gg = aa + bb + cc + dd |
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322 | |
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323 | u_int_l = ( ( gg - aa ) * u(k,j,i) + ( gg - bb ) * u(k,j,i+1) & |
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324 | + ( gg - cc ) * u(k,j+1,i) + ( gg - dd ) * & |
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325 | u(k,j+1,i+1) ) / ( 3.0_wp * gg ) - u_gtrans |
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326 | |
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327 | IF ( k == nzt ) THEN |
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328 | u_int(n) = u_int_l |
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329 | ELSE |
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330 | u_int_u = ( ( gg-aa ) * u(k+1,j,i) + ( gg-bb ) * u(k+1,j,i+1) & |
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331 | + ( gg-cc ) * u(k+1,j+1,i) + ( gg-dd ) * & |
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332 | u(k+1,j+1,i+1) ) / ( 3.0_wp * gg ) - u_gtrans |
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333 | u_int(n) = u_int_l + ( zv(n) - zu(k) ) / dz * & |
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334 | ( u_int_u - u_int_l ) |
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335 | ENDIF |
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336 | |
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337 | ENDIF |
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338 | |
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339 | ENDDO |
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340 | |
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341 | i = ip + block_offset(nb)%i_off |
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342 | j = jp |
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343 | k = kp + block_offset(nb)%k_off |
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344 | ! |
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345 | !-- Same procedure for interpolation of the v velocity-component |
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346 | DO n = start_index(nb), end_index(nb) |
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347 | |
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348 | ilog = ( particles(n)%x + 0.5_wp * dx ) * ddx |
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349 | jlog = ( particles(n)%y + 0.5_wp * dy ) * ddy |
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350 | IF ( constant_flux_layer .AND. & |
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351 | zv(n) - zw(nzb_s_inner(jlog,ilog)) < z_p ) THEN |
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352 | |
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353 | IF ( zv(n) - zw(nzb_s_inner(jlog,ilog)) < z0_av_global ) THEN |
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354 | ! |
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355 | !-- Resolved-scale horizontal particle velocity is zero below z0. |
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356 | v_int(n) = 0.0_wp |
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357 | ELSE |
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358 | ! |
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359 | !-- Determine the sublayer. Further used as index. Please note, |
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360 | !-- logarithmus can not be reused from above, as in in case of |
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361 | !-- topography particle on u-grid can be above surface-layer height, |
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362 | !-- whereas it can be below on v-grid. |
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363 | height_p = ( zv(n) - zw(nzb_s_inner(jlog,ilog)) - z0_av_global ) & |
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364 | * REAL( number_of_sublayers, KIND=wp ) & |
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365 | * d_z_p_z0 |
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366 | ! |
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367 | !-- Calculate LOG(z/z0) for exact particle height. Therefore, |
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368 | !-- interpolate linearly between precalculated logarithm. |
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369 | log_z_z0_int = log_z_z0(INT(height_p)) & |
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370 | + ( height_p - INT(height_p) ) & |
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371 | * ( log_z_z0(INT(height_p)+1) & |
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372 | - log_z_z0(INT(height_p)) & |
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373 | ) |
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374 | ! |
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375 | !-- Limit friction velocity. In narrow canyons or holes the |
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376 | !-- friction velocity can become very small, resulting in a too |
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377 | !-- large particle speed. |
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378 | us_int = MAX( 0.5_wp * ( us(jlog,ilog) + us(jlog-1,ilog) ), & |
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379 | 0.01_wp ) |
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380 | ! |
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381 | !-- Neutral solution is applied for all situations, e.g. also for |
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382 | !-- unstable and stable situations. Even though this is not exact |
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383 | !-- this saves a lot of CPU time since several calls of intrinsic |
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384 | !-- FORTRAN procedures (LOG, ATAN) are avoided, This is justified |
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385 | !-- as sensitivity studies revealed no significant effect of |
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386 | !-- using the neutral solution also for un/stable situations. |
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387 | v_int(n) = -vsws(jlog,ilog) / ( us_int * kappa + 1E-10_wp ) & |
---|
388 | * log_z_z0_int - v_gtrans |
---|
389 | |
---|
390 | ENDIF |
---|
391 | |
---|
392 | ELSE |
---|
393 | x = xv(n) - i * dx |
---|
394 | y = yv(n) + ( 0.5_wp - j ) * dy |
---|
395 | aa = x**2 + y**2 |
---|
396 | bb = ( dx - x )**2 + y**2 |
---|
397 | cc = x**2 + ( dy - y )**2 |
---|
398 | dd = ( dx - x )**2 + ( dy - y )**2 |
---|
399 | gg = aa + bb + cc + dd |
---|
400 | |
---|
401 | v_int_l = ( ( gg - aa ) * v(k,j,i) + ( gg - bb ) * v(k,j,i+1) & |
---|
402 | + ( gg - cc ) * v(k,j+1,i) + ( gg - dd ) * v(k,j+1,i+1) & |
---|
403 | ) / ( 3.0_wp * gg ) - v_gtrans |
---|
404 | |
---|
405 | IF ( k == nzt ) THEN |
---|
406 | v_int(n) = v_int_l |
---|
407 | ELSE |
---|
408 | v_int_u = ( ( gg-aa ) * v(k+1,j,i) + ( gg-bb ) * v(k+1,j,i+1) & |
---|
409 | + ( gg-cc ) * v(k+1,j+1,i) + ( gg-dd ) * v(k+1,j+1,i+1) & |
---|
410 | ) / ( 3.0_wp * gg ) - v_gtrans |
---|
411 | v_int(n) = v_int_l + ( zv(n) - zu(k) ) / dz * & |
---|
412 | ( v_int_u - v_int_l ) |
---|
413 | ENDIF |
---|
414 | |
---|
415 | ENDIF |
---|
416 | |
---|
417 | ENDDO |
---|
418 | |
---|
419 | i = ip + block_offset(nb)%i_off |
---|
420 | j = jp + block_offset(nb)%j_off |
---|
421 | k = kp - 1 |
---|
422 | ! |
---|
423 | !-- Same procedure for interpolation of the w velocity-component |
---|
424 | DO n = start_index(nb), end_index(nb) |
---|
425 | |
---|
426 | IF ( vertical_particle_advection(particles(n)%group) ) THEN |
---|
427 | |
---|
428 | x = xv(n) - i * dx |
---|
429 | y = yv(n) - j * dy |
---|
430 | aa = x**2 + y**2 |
---|
431 | bb = ( dx - x )**2 + y**2 |
---|
432 | cc = x**2 + ( dy - y )**2 |
---|
433 | dd = ( dx - x )**2 + ( dy - y )**2 |
---|
434 | gg = aa + bb + cc + dd |
---|
435 | |
---|
436 | w_int_l = ( ( gg - aa ) * w(k,j,i) + ( gg - bb ) * w(k,j,i+1) & |
---|
437 | + ( gg - cc ) * w(k,j+1,i) + ( gg - dd ) * w(k,j+1,i+1) & |
---|
438 | ) / ( 3.0_wp * gg ) |
---|
439 | |
---|
440 | IF ( k == nzt ) THEN |
---|
441 | w_int(n) = w_int_l |
---|
442 | ELSE |
---|
443 | w_int_u = ( ( gg-aa ) * w(k+1,j,i) + & |
---|
444 | ( gg-bb ) * w(k+1,j,i+1) + & |
---|
445 | ( gg-cc ) * w(k+1,j+1,i) + & |
---|
446 | ( gg-dd ) * w(k+1,j+1,i+1) & |
---|
447 | ) / ( 3.0_wp * gg ) |
---|
448 | w_int(n) = w_int_l + ( zv(n) - zw(k) ) / dz * & |
---|
449 | ( w_int_u - w_int_l ) |
---|
450 | ENDIF |
---|
451 | |
---|
452 | ELSE |
---|
453 | |
---|
454 | w_int(n) = 0.0_wp |
---|
455 | |
---|
456 | ENDIF |
---|
457 | |
---|
458 | ENDDO |
---|
459 | |
---|
460 | ENDDO |
---|
461 | |
---|
462 | !-- Interpolate and calculate quantities needed for calculating the SGS |
---|
463 | !-- velocities |
---|
464 | IF ( use_sgs_for_particles .AND. .NOT. cloud_droplets ) THEN |
---|
465 | |
---|
466 | IF ( topography == 'flat' ) THEN |
---|
467 | |
---|
468 | DO nb = 0,7 |
---|
469 | |
---|
470 | i = ip + block_offset(nb)%i_off |
---|
471 | j = jp + block_offset(nb)%j_off |
---|
472 | k = kp + block_offset(nb)%k_off |
---|
473 | |
---|
474 | DO n = start_index(nb), end_index(nb) |
---|
475 | ! |
---|
476 | !-- Interpolate TKE |
---|
477 | x = xv(n) - i * dx |
---|
478 | y = yv(n) - j * dy |
---|
479 | aa = x**2 + y**2 |
---|
480 | bb = ( dx - x )**2 + y**2 |
---|
481 | cc = x**2 + ( dy - y )**2 |
---|
482 | dd = ( dx - x )**2 + ( dy - y )**2 |
---|
483 | gg = aa + bb + cc + dd |
---|
484 | |
---|
485 | e_int_l = ( ( gg-aa ) * e(k,j,i) + ( gg-bb ) * e(k,j,i+1) & |
---|
486 | + ( gg-cc ) * e(k,j+1,i) + ( gg-dd ) * e(k,j+1,i+1) & |
---|
487 | ) / ( 3.0_wp * gg ) |
---|
488 | |
---|
489 | IF ( k+1 == nzt+1 ) THEN |
---|
490 | e_int(n) = e_int_l |
---|
491 | ELSE |
---|
492 | e_int_u = ( ( gg - aa ) * e(k+1,j,i) + & |
---|
493 | ( gg - bb ) * e(k+1,j,i+1) + & |
---|
494 | ( gg - cc ) * e(k+1,j+1,i) + & |
---|
495 | ( gg - dd ) * e(k+1,j+1,i+1) & |
---|
496 | ) / ( 3.0_wp * gg ) |
---|
497 | e_int(n) = e_int_l + ( zv(n) - zu(k) ) / dz * & |
---|
498 | ( e_int_u - e_int_l ) |
---|
499 | ENDIF |
---|
500 | ! |
---|
501 | !-- Needed to avoid NaN particle velocities (this might not be |
---|
502 | !-- required any more) |
---|
503 | IF ( e_int(n) <= 0.0_wp ) THEN |
---|
504 | e_int(n) = 1.0E-20_wp |
---|
505 | ENDIF |
---|
506 | ! |
---|
507 | !-- Interpolate the TKE gradient along x (adopt incides i,j,k and |
---|
508 | !-- all position variables from above (TKE)) |
---|
509 | de_dx_int_l = ( ( gg - aa ) * de_dx(k,j,i) + & |
---|
510 | ( gg - bb ) * de_dx(k,j,i+1) + & |
---|
511 | ( gg - cc ) * de_dx(k,j+1,i) + & |
---|
512 | ( gg - dd ) * de_dx(k,j+1,i+1) & |
---|
513 | ) / ( 3.0_wp * gg ) |
---|
514 | |
---|
515 | IF ( ( k+1 == nzt+1 ) .OR. ( k == nzb ) ) THEN |
---|
516 | de_dx_int(n) = de_dx_int_l |
---|
517 | ELSE |
---|
518 | de_dx_int_u = ( ( gg - aa ) * de_dx(k+1,j,i) + & |
---|
519 | ( gg - bb ) * de_dx(k+1,j,i+1) + & |
---|
520 | ( gg - cc ) * de_dx(k+1,j+1,i) + & |
---|
521 | ( gg - dd ) * de_dx(k+1,j+1,i+1) & |
---|
522 | ) / ( 3.0_wp * gg ) |
---|
523 | de_dx_int(n) = de_dx_int_l + ( zv(n) - zu(k) ) / dz * & |
---|
524 | ( de_dx_int_u - de_dx_int_l ) |
---|
525 | ENDIF |
---|
526 | ! |
---|
527 | !-- Interpolate the TKE gradient along y |
---|
528 | de_dy_int_l = ( ( gg - aa ) * de_dy(k,j,i) + & |
---|
529 | ( gg - bb ) * de_dy(k,j,i+1) + & |
---|
530 | ( gg - cc ) * de_dy(k,j+1,i) + & |
---|
531 | ( gg - dd ) * de_dy(k,j+1,i+1) & |
---|
532 | ) / ( 3.0_wp * gg ) |
---|
533 | IF ( ( k+1 == nzt+1 ) .OR. ( k == nzb ) ) THEN |
---|
534 | de_dy_int(n) = de_dy_int_l |
---|
535 | ELSE |
---|
536 | de_dy_int_u = ( ( gg - aa ) * de_dy(k+1,j,i) + & |
---|
537 | ( gg - bb ) * de_dy(k+1,j,i+1) + & |
---|
538 | ( gg - cc ) * de_dy(k+1,j+1,i) + & |
---|
539 | ( gg - dd ) * de_dy(k+1,j+1,i+1) & |
---|
540 | ) / ( 3.0_wp * gg ) |
---|
541 | de_dy_int(n) = de_dy_int_l + ( zv(n) - zu(k) ) / dz * & |
---|
542 | ( de_dy_int_u - de_dy_int_l ) |
---|
543 | ENDIF |
---|
544 | |
---|
545 | ! |
---|
546 | !-- Interpolate the TKE gradient along z |
---|
547 | IF ( zv(n) < 0.5_wp * dz ) THEN |
---|
548 | de_dz_int(n) = 0.0_wp |
---|
549 | ELSE |
---|
550 | de_dz_int_l = ( ( gg - aa ) * de_dz(k,j,i) + & |
---|
551 | ( gg - bb ) * de_dz(k,j,i+1) + & |
---|
552 | ( gg - cc ) * de_dz(k,j+1,i) + & |
---|
553 | ( gg - dd ) * de_dz(k,j+1,i+1) & |
---|
554 | ) / ( 3.0_wp * gg ) |
---|
555 | |
---|
556 | IF ( ( k+1 == nzt+1 ) .OR. ( k == nzb ) ) THEN |
---|
557 | de_dz_int(n) = de_dz_int_l |
---|
558 | ELSE |
---|
559 | de_dz_int_u = ( ( gg - aa ) * de_dz(k+1,j,i) + & |
---|
560 | ( gg - bb ) * de_dz(k+1,j,i+1) + & |
---|
561 | ( gg - cc ) * de_dz(k+1,j+1,i) + & |
---|
562 | ( gg - dd ) * de_dz(k+1,j+1,i+1) & |
---|
563 | ) / ( 3.0_wp * gg ) |
---|
564 | de_dz_int(n) = de_dz_int_l + ( zv(n) - zu(k) ) / dz * & |
---|
565 | ( de_dz_int_u - de_dz_int_l ) |
---|
566 | ENDIF |
---|
567 | ENDIF |
---|
568 | |
---|
569 | ! |
---|
570 | !-- Interpolate the dissipation of TKE |
---|
571 | diss_int_l = ( ( gg - aa ) * diss(k,j,i) + & |
---|
572 | ( gg - bb ) * diss(k,j,i+1) + & |
---|
573 | ( gg - cc ) * diss(k,j+1,i) + & |
---|
574 | ( gg - dd ) * diss(k,j+1,i+1) & |
---|
575 | ) / ( 3.0_wp * gg ) |
---|
576 | |
---|
577 | IF ( k == nzt ) THEN |
---|
578 | diss_int(n) = diss_int_l |
---|
579 | ELSE |
---|
580 | diss_int_u = ( ( gg - aa ) * diss(k+1,j,i) + & |
---|
581 | ( gg - bb ) * diss(k+1,j,i+1) + & |
---|
582 | ( gg - cc ) * diss(k+1,j+1,i) + & |
---|
583 | ( gg - dd ) * diss(k+1,j+1,i+1) & |
---|
584 | ) / ( 3.0_wp * gg ) |
---|
585 | diss_int(n) = diss_int_l + ( zv(n) - zu(k) ) / dz * & |
---|
586 | ( diss_int_u - diss_int_l ) |
---|
587 | ENDIF |
---|
588 | |
---|
589 | ! |
---|
590 | !-- Set flag for stochastic equation. |
---|
591 | term_1_2(n) = 1.0_wp |
---|
592 | |
---|
593 | ENDDO |
---|
594 | ENDDO |
---|
595 | |
---|
596 | ELSE ! non-flat topography, e.g., buildings |
---|
597 | |
---|
598 | DO n = 1, number_of_particles |
---|
599 | i = particles(n)%x * ddx |
---|
600 | j = particles(n)%y * ddy |
---|
601 | k = ( zv(n) + 0.5_wp * dz * atmos_ocean_sign ) / dz & |
---|
602 | + offset_ocean_nzt ! only exact if eq.dist |
---|
603 | ! |
---|
604 | !-- In case that there are buildings it has to be determined |
---|
605 | !-- how many of the gridpoints defining the particle box are |
---|
606 | !-- situated within a building |
---|
607 | !-- gp_outside_of_building(1): i,j,k |
---|
608 | !-- gp_outside_of_building(2): i,j+1,k |
---|
609 | !-- gp_outside_of_building(3): i,j,k+1 |
---|
610 | !-- gp_outside_of_building(4): i,j+1,k+1 |
---|
611 | !-- gp_outside_of_building(5): i+1,j,k |
---|
612 | !-- gp_outside_of_building(6): i+1,j+1,k |
---|
613 | !-- gp_outside_of_building(7): i+1,j,k+1 |
---|
614 | !-- gp_outside_of_building(8): i+1,j+1,k+1 |
---|
615 | |
---|
616 | gp_outside_of_building = 0 |
---|
617 | location = 0.0_wp |
---|
618 | num_gp = 0 |
---|
619 | |
---|
620 | IF ( k > nzb_s_inner(j,i) .OR. nzb_s_inner(j,i) == 0 ) THEN |
---|
621 | num_gp = num_gp + 1 |
---|
622 | gp_outside_of_building(1) = 1 |
---|
623 | location(num_gp,1) = i * dx |
---|
624 | location(num_gp,2) = j * dy |
---|
625 | location(num_gp,3) = k * dz - 0.5_wp * dz |
---|
626 | ei(num_gp) = e(k,j,i) |
---|
627 | dissi(num_gp) = diss(k,j,i) |
---|
628 | de_dxi(num_gp) = de_dx(k,j,i) |
---|
629 | de_dyi(num_gp) = de_dy(k,j,i) |
---|
630 | de_dzi(num_gp) = de_dz(k,j,i) |
---|
631 | ENDIF |
---|
632 | IF ( k > nzb_s_inner(j+1,i) .OR. nzb_s_inner(j+1,i) == 0 ) THEN |
---|
633 | num_gp = num_gp + 1 |
---|
634 | gp_outside_of_building(2) = 1 |
---|
635 | location(num_gp,1) = i * dx |
---|
636 | location(num_gp,2) = (j+1) * dy |
---|
637 | location(num_gp,3) = k * dz - 0.5_wp * dz |
---|
638 | ei(num_gp) = e(k,j+1,i) |
---|
639 | dissi(num_gp) = diss(k,j+1,i) |
---|
640 | de_dxi(num_gp) = de_dx(k,j+1,i) |
---|
641 | de_dyi(num_gp) = de_dy(k,j+1,i) |
---|
642 | de_dzi(num_gp) = de_dz(k,j+1,i) |
---|
643 | ENDIF |
---|
644 | |
---|
645 | IF ( k+1 > nzb_s_inner(j,i) .OR. nzb_s_inner(j,i) == 0 ) THEN |
---|
646 | num_gp = num_gp + 1 |
---|
647 | gp_outside_of_building(3) = 1 |
---|
648 | location(num_gp,1) = i * dx |
---|
649 | location(num_gp,2) = j * dy |
---|
650 | location(num_gp,3) = (k+1) * dz - 0.5_wp * dz |
---|
651 | ei(num_gp) = e(k+1,j,i) |
---|
652 | dissi(num_gp) = diss(k+1,j,i) |
---|
653 | de_dxi(num_gp) = de_dx(k+1,j,i) |
---|
654 | de_dyi(num_gp) = de_dy(k+1,j,i) |
---|
655 | de_dzi(num_gp) = de_dz(k+1,j,i) |
---|
656 | ENDIF |
---|
657 | |
---|
658 | IF ( k+1 > nzb_s_inner(j+1,i) .OR. nzb_s_inner(j+1,i) == 0 ) THEN |
---|
659 | num_gp = num_gp + 1 |
---|
660 | gp_outside_of_building(4) = 1 |
---|
661 | location(num_gp,1) = i * dx |
---|
662 | location(num_gp,2) = (j+1) * dy |
---|
663 | location(num_gp,3) = (k+1) * dz - 0.5_wp * dz |
---|
664 | ei(num_gp) = e(k+1,j+1,i) |
---|
665 | dissi(num_gp) = diss(k+1,j+1,i) |
---|
666 | de_dxi(num_gp) = de_dx(k+1,j+1,i) |
---|
667 | de_dyi(num_gp) = de_dy(k+1,j+1,i) |
---|
668 | de_dzi(num_gp) = de_dz(k+1,j+1,i) |
---|
669 | ENDIF |
---|
670 | |
---|
671 | IF ( k > nzb_s_inner(j,i+1) .OR. nzb_s_inner(j,i+1) == 0 ) THEN |
---|
672 | num_gp = num_gp + 1 |
---|
673 | gp_outside_of_building(5) = 1 |
---|
674 | location(num_gp,1) = (i+1) * dx |
---|
675 | location(num_gp,2) = j * dy |
---|
676 | location(num_gp,3) = k * dz - 0.5_wp * dz |
---|
677 | ei(num_gp) = e(k,j,i+1) |
---|
678 | dissi(num_gp) = diss(k,j,i+1) |
---|
679 | de_dxi(num_gp) = de_dx(k,j,i+1) |
---|
680 | de_dyi(num_gp) = de_dy(k,j,i+1) |
---|
681 | de_dzi(num_gp) = de_dz(k,j,i+1) |
---|
682 | ENDIF |
---|
683 | |
---|
684 | IF ( k > nzb_s_inner(j+1,i+1) .OR. nzb_s_inner(j+1,i+1) == 0 ) THEN |
---|
685 | num_gp = num_gp + 1 |
---|
686 | gp_outside_of_building(6) = 1 |
---|
687 | location(num_gp,1) = (i+1) * dx |
---|
688 | location(num_gp,2) = (j+1) * dy |
---|
689 | location(num_gp,3) = k * dz - 0.5_wp * dz |
---|
690 | ei(num_gp) = e(k,j+1,i+1) |
---|
691 | dissi(num_gp) = diss(k,j+1,i+1) |
---|
692 | de_dxi(num_gp) = de_dx(k,j+1,i+1) |
---|
693 | de_dyi(num_gp) = de_dy(k,j+1,i+1) |
---|
694 | de_dzi(num_gp) = de_dz(k,j+1,i+1) |
---|
695 | ENDIF |
---|
696 | |
---|
697 | IF ( k+1 > nzb_s_inner(j,i+1) .OR. nzb_s_inner(j,i+1) == 0 ) THEN |
---|
698 | num_gp = num_gp + 1 |
---|
699 | gp_outside_of_building(7) = 1 |
---|
700 | location(num_gp,1) = (i+1) * dx |
---|
701 | location(num_gp,2) = j * dy |
---|
702 | location(num_gp,3) = (k+1) * dz - 0.5_wp * dz |
---|
703 | ei(num_gp) = e(k+1,j,i+1) |
---|
704 | dissi(num_gp) = diss(k+1,j,i+1) |
---|
705 | de_dxi(num_gp) = de_dx(k+1,j,i+1) |
---|
706 | de_dyi(num_gp) = de_dy(k+1,j,i+1) |
---|
707 | de_dzi(num_gp) = de_dz(k+1,j,i+1) |
---|
708 | ENDIF |
---|
709 | |
---|
710 | IF ( k+1 > nzb_s_inner(j+1,i+1) .OR. nzb_s_inner(j+1,i+1) == 0) THEN |
---|
711 | num_gp = num_gp + 1 |
---|
712 | gp_outside_of_building(8) = 1 |
---|
713 | location(num_gp,1) = (i+1) * dx |
---|
714 | location(num_gp,2) = (j+1) * dy |
---|
715 | location(num_gp,3) = (k+1) * dz - 0.5_wp * dz |
---|
716 | ei(num_gp) = e(k+1,j+1,i+1) |
---|
717 | dissi(num_gp) = diss(k+1,j+1,i+1) |
---|
718 | de_dxi(num_gp) = de_dx(k+1,j+1,i+1) |
---|
719 | de_dyi(num_gp) = de_dy(k+1,j+1,i+1) |
---|
720 | de_dzi(num_gp) = de_dz(k+1,j+1,i+1) |
---|
721 | ENDIF |
---|
722 | ! |
---|
723 | !-- If all gridpoints are situated outside of a building, then the |
---|
724 | !-- ordinary interpolation scheme can be used. |
---|
725 | IF ( num_gp == 8 ) THEN |
---|
726 | |
---|
727 | x = particles(n)%x - i * dx |
---|
728 | y = particles(n)%y - j * dy |
---|
729 | aa = x**2 + y**2 |
---|
730 | bb = ( dx - x )**2 + y**2 |
---|
731 | cc = x**2 + ( dy - y )**2 |
---|
732 | dd = ( dx - x )**2 + ( dy - y )**2 |
---|
733 | gg = aa + bb + cc + dd |
---|
734 | |
---|
735 | e_int_l = ( ( gg - aa ) * e(k,j,i) + ( gg - bb ) * e(k,j,i+1) & |
---|
736 | + ( gg - cc ) * e(k,j+1,i) + ( gg - dd ) * e(k,j+1,i+1) & |
---|
737 | ) / ( 3.0_wp * gg ) |
---|
738 | |
---|
739 | IF ( k == nzt ) THEN |
---|
740 | e_int(n) = e_int_l |
---|
741 | ELSE |
---|
742 | e_int_u = ( ( gg - aa ) * e(k+1,j,i) + & |
---|
743 | ( gg - bb ) * e(k+1,j,i+1) + & |
---|
744 | ( gg - cc ) * e(k+1,j+1,i) + & |
---|
745 | ( gg - dd ) * e(k+1,j+1,i+1) & |
---|
746 | ) / ( 3.0_wp * gg ) |
---|
747 | e_int(n) = e_int_l + ( zv(n) - zu(k) ) / dz * & |
---|
748 | ( e_int_u - e_int_l ) |
---|
749 | ENDIF |
---|
750 | ! |
---|
751 | !-- Needed to avoid NaN particle velocities (this might not be |
---|
752 | !-- required any more) |
---|
753 | IF ( e_int(n) <= 0.0_wp ) THEN |
---|
754 | e_int(n) = 1.0E-20_wp |
---|
755 | ENDIF |
---|
756 | ! |
---|
757 | !-- Interpolate the TKE gradient along x (adopt incides i,j,k |
---|
758 | !-- and all position variables from above (TKE)) |
---|
759 | de_dx_int_l = ( ( gg - aa ) * de_dx(k,j,i) + & |
---|
760 | ( gg - bb ) * de_dx(k,j,i+1) + & |
---|
761 | ( gg - cc ) * de_dx(k,j+1,i) + & |
---|
762 | ( gg - dd ) * de_dx(k,j+1,i+1) & |
---|
763 | ) / ( 3.0_wp * gg ) |
---|
764 | |
---|
765 | IF ( ( k == nzt ) .OR. ( k == nzb ) ) THEN |
---|
766 | de_dx_int(n) = de_dx_int_l |
---|
767 | ELSE |
---|
768 | de_dx_int_u = ( ( gg - aa ) * de_dx(k+1,j,i) + & |
---|
769 | ( gg - bb ) * de_dx(k+1,j,i+1) + & |
---|
770 | ( gg - cc ) * de_dx(k+1,j+1,i) + & |
---|
771 | ( gg - dd ) * de_dx(k+1,j+1,i+1) & |
---|
772 | ) / ( 3.0_wp * gg ) |
---|
773 | de_dx_int(n) = de_dx_int_l + ( zv(n) - zu(k) ) / & |
---|
774 | dz * ( de_dx_int_u - de_dx_int_l ) |
---|
775 | ENDIF |
---|
776 | |
---|
777 | ! |
---|
778 | !-- Interpolate the TKE gradient along y |
---|
779 | de_dy_int_l = ( ( gg - aa ) * de_dy(k,j,i) + & |
---|
780 | ( gg - bb ) * de_dy(k,j,i+1) + & |
---|
781 | ( gg - cc ) * de_dy(k,j+1,i) + & |
---|
782 | ( gg - dd ) * de_dy(k,j+1,i+1) & |
---|
783 | ) / ( 3.0_wp * gg ) |
---|
784 | IF ( ( k+1 == nzt+1 ) .OR. ( k == nzb ) ) THEN |
---|
785 | de_dy_int(n) = de_dy_int_l |
---|
786 | ELSE |
---|
787 | de_dy_int_u = ( ( gg - aa ) * de_dy(k+1,j,i) + & |
---|
788 | ( gg - bb ) * de_dy(k+1,j,i+1) + & |
---|
789 | ( gg - cc ) * de_dy(k+1,j+1,i) + & |
---|
790 | ( gg - dd ) * de_dy(k+1,j+1,i+1) & |
---|
791 | ) / ( 3.0_wp * gg ) |
---|
792 | de_dy_int(n) = de_dy_int_l + ( zv(n) - zu(k) ) / & |
---|
793 | dz * ( de_dy_int_u - de_dy_int_l ) |
---|
794 | ENDIF |
---|
795 | |
---|
796 | ! |
---|
797 | !-- Interpolate the TKE gradient along z |
---|
798 | IF ( zv(n) < 0.5_wp * dz ) THEN |
---|
799 | de_dz_int(n) = 0.0_wp |
---|
800 | ELSE |
---|
801 | de_dz_int_l = ( ( gg - aa ) * de_dz(k,j,i) + & |
---|
802 | ( gg - bb ) * de_dz(k,j,i+1) + & |
---|
803 | ( gg - cc ) * de_dz(k,j+1,i) + & |
---|
804 | ( gg - dd ) * de_dz(k,j+1,i+1) & |
---|
805 | ) / ( 3.0_wp * gg ) |
---|
806 | |
---|
807 | IF ( ( k+1 == nzt+1 ) .OR. ( k == nzb ) ) THEN |
---|
808 | de_dz_int(n) = de_dz_int_l |
---|
809 | ELSE |
---|
810 | de_dz_int_u = ( ( gg - aa ) * de_dz(k+1,j,i) + & |
---|
811 | ( gg - bb ) * de_dz(k+1,j,i+1) + & |
---|
812 | ( gg - cc ) * de_dz(k+1,j+1,i) + & |
---|
813 | ( gg - dd ) * de_dz(k+1,j+1,i+1) & |
---|
814 | ) / ( 3.0_wp * gg ) |
---|
815 | de_dz_int(n) = de_dz_int_l + ( zv(n) - zu(k) ) /& |
---|
816 | dz * ( de_dz_int_u - de_dz_int_l ) |
---|
817 | ENDIF |
---|
818 | ENDIF |
---|
819 | |
---|
820 | ! |
---|
821 | !-- Interpolate the dissipation of TKE |
---|
822 | diss_int_l = ( ( gg - aa ) * diss(k,j,i) + & |
---|
823 | ( gg - bb ) * diss(k,j,i+1) + & |
---|
824 | ( gg - cc ) * diss(k,j+1,i) + & |
---|
825 | ( gg - dd ) * diss(k,j+1,i+1) & |
---|
826 | ) / ( 3.0_wp * gg ) |
---|
827 | |
---|
828 | IF ( k == nzt ) THEN |
---|
829 | diss_int(n) = diss_int_l |
---|
830 | ELSE |
---|
831 | diss_int_u = ( ( gg - aa ) * diss(k+1,j,i) + & |
---|
832 | ( gg - bb ) * diss(k+1,j,i+1) + & |
---|
833 | ( gg - cc ) * diss(k+1,j+1,i) + & |
---|
834 | ( gg - dd ) * diss(k+1,j+1,i+1) & |
---|
835 | ) / ( 3.0_wp * gg ) |
---|
836 | diss_int(n) = diss_int_l + ( zv(n) - zu(k) ) / dz *& |
---|
837 | ( diss_int_u - diss_int_l ) |
---|
838 | ENDIF |
---|
839 | ! |
---|
840 | !-- Set flag for stochastic equation. |
---|
841 | term_1_2(n) = 1.0_wp |
---|
842 | |
---|
843 | ELSE |
---|
844 | |
---|
845 | ! |
---|
846 | !-- If wall between gridpoint 1 and gridpoint 5, then |
---|
847 | !-- Neumann boundary condition has to be applied |
---|
848 | IF ( gp_outside_of_building(1) == 1 .AND. & |
---|
849 | gp_outside_of_building(5) == 0 ) THEN |
---|
850 | num_gp = num_gp + 1 |
---|
851 | location(num_gp,1) = i * dx + 0.5_wp * dx |
---|
852 | location(num_gp,2) = j * dy |
---|
853 | location(num_gp,3) = k * dz - 0.5_wp * dz |
---|
854 | ei(num_gp) = e(k,j,i) |
---|
855 | dissi(num_gp) = diss(k,j,i) |
---|
856 | de_dxi(num_gp) = 0.0_wp |
---|
857 | de_dyi(num_gp) = de_dy(k,j,i) |
---|
858 | de_dzi(num_gp) = de_dz(k,j,i) |
---|
859 | ENDIF |
---|
860 | |
---|
861 | IF ( gp_outside_of_building(5) == 1 .AND. & |
---|
862 | gp_outside_of_building(1) == 0 ) THEN |
---|
863 | num_gp = num_gp + 1 |
---|
864 | location(num_gp,1) = i * dx + 0.5_wp * dx |
---|
865 | location(num_gp,2) = j * dy |
---|
866 | location(num_gp,3) = k * dz - 0.5_wp * dz |
---|
867 | ei(num_gp) = e(k,j,i+1) |
---|
868 | dissi(num_gp) = diss(k,j,i+1) |
---|
869 | de_dxi(num_gp) = 0.0_wp |
---|
870 | de_dyi(num_gp) = de_dy(k,j,i+1) |
---|
871 | de_dzi(num_gp) = de_dz(k,j,i+1) |
---|
872 | ENDIF |
---|
873 | |
---|
874 | ! |
---|
875 | !-- If wall between gridpoint 5 and gridpoint 6, then |
---|
876 | !-- then Neumann boundary condition has to be applied |
---|
877 | IF ( gp_outside_of_building(5) == 1 .AND. & |
---|
878 | gp_outside_of_building(6) == 0 ) THEN |
---|
879 | num_gp = num_gp + 1 |
---|
880 | location(num_gp,1) = (i+1) * dx |
---|
881 | location(num_gp,2) = j * dy + 0.5_wp * dy |
---|
882 | location(num_gp,3) = k * dz - 0.5_wp * dz |
---|
883 | ei(num_gp) = e(k,j,i+1) |
---|
884 | dissi(num_gp) = diss(k,j,i+1) |
---|
885 | de_dxi(num_gp) = de_dx(k,j,i+1) |
---|
886 | de_dyi(num_gp) = 0.0_wp |
---|
887 | de_dzi(num_gp) = de_dz(k,j,i+1) |
---|
888 | ENDIF |
---|
889 | |
---|
890 | IF ( gp_outside_of_building(6) == 1 .AND. & |
---|
891 | gp_outside_of_building(5) == 0 ) THEN |
---|
892 | num_gp = num_gp + 1 |
---|
893 | location(num_gp,1) = (i+1) * dx |
---|
894 | location(num_gp,2) = j * dy + 0.5_wp * dy |
---|
895 | location(num_gp,3) = k * dz - 0.5_wp * dz |
---|
896 | ei(num_gp) = e(k,j+1,i+1) |
---|
897 | dissi(num_gp) = diss(k,j+1,i+1) |
---|
898 | de_dxi(num_gp) = de_dx(k,j+1,i+1) |
---|
899 | de_dyi(num_gp) = 0.0_wp |
---|
900 | de_dzi(num_gp) = de_dz(k,j+1,i+1) |
---|
901 | ENDIF |
---|
902 | |
---|
903 | ! |
---|
904 | !-- If wall between gridpoint 2 and gridpoint 6, then |
---|
905 | !-- Neumann boundary condition has to be applied |
---|
906 | IF ( gp_outside_of_building(2) == 1 .AND. & |
---|
907 | gp_outside_of_building(6) == 0 ) THEN |
---|
908 | num_gp = num_gp + 1 |
---|
909 | location(num_gp,1) = i * dx + 0.5_wp * dx |
---|
910 | location(num_gp,2) = (j+1) * dy |
---|
911 | location(num_gp,3) = k * dz - 0.5_wp * dz |
---|
912 | ei(num_gp) = e(k,j+1,i) |
---|
913 | dissi(num_gp) = diss(k,j+1,i) |
---|
914 | de_dxi(num_gp) = 0.0_wp |
---|
915 | de_dyi(num_gp) = de_dy(k,j+1,i) |
---|
916 | de_dzi(num_gp) = de_dz(k,j+1,i) |
---|
917 | ENDIF |
---|
918 | |
---|
919 | IF ( gp_outside_of_building(6) == 1 .AND. & |
---|
920 | gp_outside_of_building(2) == 0 ) THEN |
---|
921 | num_gp = num_gp + 1 |
---|
922 | location(num_gp,1) = i * dx + 0.5_wp * dx |
---|
923 | location(num_gp,2) = (j+1) * dy |
---|
924 | location(num_gp,3) = k * dz - 0.5_wp * dz |
---|
925 | ei(num_gp) = e(k,j+1,i+1) |
---|
926 | dissi(num_gp) = diss(k,j+1,i+1) |
---|
927 | de_dxi(num_gp) = 0.0_wp |
---|
928 | de_dyi(num_gp) = de_dy(k,j+1,i+1) |
---|
929 | de_dzi(num_gp) = de_dz(k,j+1,i+1) |
---|
930 | ENDIF |
---|
931 | |
---|
932 | ! |
---|
933 | !-- If wall between gridpoint 1 and gridpoint 2, then |
---|
934 | !-- Neumann boundary condition has to be applied |
---|
935 | IF ( gp_outside_of_building(1) == 1 .AND. & |
---|
936 | gp_outside_of_building(2) == 0 ) THEN |
---|
937 | num_gp = num_gp + 1 |
---|
938 | location(num_gp,1) = i * dx |
---|
939 | location(num_gp,2) = j * dy + 0.5_wp * dy |
---|
940 | location(num_gp,3) = k * dz - 0.5_wp * dz |
---|
941 | ei(num_gp) = e(k,j,i) |
---|
942 | dissi(num_gp) = diss(k,j,i) |
---|
943 | de_dxi(num_gp) = de_dx(k,j,i) |
---|
944 | de_dyi(num_gp) = 0.0_wp |
---|
945 | de_dzi(num_gp) = de_dz(k,j,i) |
---|
946 | ENDIF |
---|
947 | |
---|
948 | IF ( gp_outside_of_building(2) == 1 .AND. & |
---|
949 | gp_outside_of_building(1) == 0 ) THEN |
---|
950 | num_gp = num_gp + 1 |
---|
951 | location(num_gp,1) = i * dx |
---|
952 | location(num_gp,2) = j * dy + 0.5_wp * dy |
---|
953 | location(num_gp,3) = k * dz - 0.5_wp * dz |
---|
954 | ei(num_gp) = e(k,j+1,i) |
---|
955 | dissi(num_gp) = diss(k,j+1,i) |
---|
956 | de_dxi(num_gp) = de_dx(k,j+1,i) |
---|
957 | de_dyi(num_gp) = 0.0_wp |
---|
958 | de_dzi(num_gp) = de_dz(k,j+1,i) |
---|
959 | ENDIF |
---|
960 | |
---|
961 | ! |
---|
962 | !-- If wall between gridpoint 3 and gridpoint 7, then |
---|
963 | !-- Neumann boundary condition has to be applied |
---|
964 | IF ( gp_outside_of_building(3) == 1 .AND. & |
---|
965 | gp_outside_of_building(7) == 0 ) THEN |
---|
966 | num_gp = num_gp + 1 |
---|
967 | location(num_gp,1) = i * dx + 0.5_wp * dx |
---|
968 | location(num_gp,2) = j * dy |
---|
969 | location(num_gp,3) = k * dz + 0.5_wp * dz |
---|
970 | ei(num_gp) = e(k+1,j,i) |
---|
971 | dissi(num_gp) = diss(k+1,j,i) |
---|
972 | de_dxi(num_gp) = 0.0_wp |
---|
973 | de_dyi(num_gp) = de_dy(k+1,j,i) |
---|
974 | de_dzi(num_gp) = de_dz(k+1,j,i) |
---|
975 | ENDIF |
---|
976 | |
---|
977 | IF ( gp_outside_of_building(7) == 1 .AND. & |
---|
978 | gp_outside_of_building(3) == 0 ) THEN |
---|
979 | num_gp = num_gp + 1 |
---|
980 | location(num_gp,1) = i * dx + 0.5_wp * dx |
---|
981 | location(num_gp,2) = j * dy |
---|
982 | location(num_gp,3) = k * dz + 0.5_wp * dz |
---|
983 | ei(num_gp) = e(k+1,j,i+1) |
---|
984 | dissi(num_gp) = diss(k+1,j,i+1) |
---|
985 | de_dxi(num_gp) = 0.0_wp |
---|
986 | de_dyi(num_gp) = de_dy(k+1,j,i+1) |
---|
987 | de_dzi(num_gp) = de_dz(k+1,j,i+1) |
---|
988 | ENDIF |
---|
989 | |
---|
990 | ! |
---|
991 | !-- If wall between gridpoint 7 and gridpoint 8, then |
---|
992 | !-- Neumann boundary condition has to be applied |
---|
993 | IF ( gp_outside_of_building(7) == 1 .AND. & |
---|
994 | gp_outside_of_building(8) == 0 ) THEN |
---|
995 | num_gp = num_gp + 1 |
---|
996 | location(num_gp,1) = (i+1) * dx |
---|
997 | location(num_gp,2) = j * dy + 0.5_wp * dy |
---|
998 | location(num_gp,3) = k * dz + 0.5_wp * dz |
---|
999 | ei(num_gp) = e(k+1,j,i+1) |
---|
1000 | dissi(num_gp) = diss(k+1,j,i+1) |
---|
1001 | de_dxi(num_gp) = de_dx(k+1,j,i+1) |
---|
1002 | de_dyi(num_gp) = 0.0_wp |
---|
1003 | de_dzi(num_gp) = de_dz(k+1,j,i+1) |
---|
1004 | ENDIF |
---|
1005 | |
---|
1006 | IF ( gp_outside_of_building(8) == 1 .AND. & |
---|
1007 | gp_outside_of_building(7) == 0 ) THEN |
---|
1008 | num_gp = num_gp + 1 |
---|
1009 | location(num_gp,1) = (i+1) * dx |
---|
1010 | location(num_gp,2) = j * dy + 0.5_wp * dy |
---|
1011 | location(num_gp,3) = k * dz + 0.5_wp * dz |
---|
1012 | ei(num_gp) = e(k+1,j+1,i+1) |
---|
1013 | dissi(num_gp) = diss(k+1,j+1,i+1) |
---|
1014 | de_dxi(num_gp) = de_dx(k+1,j+1,i+1) |
---|
1015 | de_dyi(num_gp) = 0.0_wp |
---|
1016 | de_dzi(num_gp) = de_dz(k+1,j+1,i+1) |
---|
1017 | ENDIF |
---|
1018 | |
---|
1019 | ! |
---|
1020 | !-- If wall between gridpoint 4 and gridpoint 8, then |
---|
1021 | !-- Neumann boundary condition has to be applied |
---|
1022 | IF ( gp_outside_of_building(4) == 1 .AND. & |
---|
1023 | gp_outside_of_building(8) == 0 ) THEN |
---|
1024 | num_gp = num_gp + 1 |
---|
1025 | location(num_gp,1) = i * dx + 0.5_wp * dx |
---|
1026 | location(num_gp,2) = (j+1) * dy |
---|
1027 | location(num_gp,3) = k * dz + 0.5_wp * dz |
---|
1028 | ei(num_gp) = e(k+1,j+1,i) |
---|
1029 | dissi(num_gp) = diss(k+1,j+1,i) |
---|
1030 | de_dxi(num_gp) = 0.0_wp |
---|
1031 | de_dyi(num_gp) = de_dy(k+1,j+1,i) |
---|
1032 | de_dzi(num_gp) = de_dz(k+1,j+1,i) |
---|
1033 | ENDIF |
---|
1034 | |
---|
1035 | IF ( gp_outside_of_building(8) == 1 .AND. & |
---|
1036 | gp_outside_of_building(4) == 0 ) THEN |
---|
1037 | num_gp = num_gp + 1 |
---|
1038 | location(num_gp,1) = i * dx + 0.5_wp * dx |
---|
1039 | location(num_gp,2) = (j+1) * dy |
---|
1040 | location(num_gp,3) = k * dz + 0.5_wp * dz |
---|
1041 | ei(num_gp) = e(k+1,j+1,i+1) |
---|
1042 | dissi(num_gp) = diss(k+1,j+1,i+1) |
---|
1043 | de_dxi(num_gp) = 0.0_wp |
---|
1044 | de_dyi(num_gp) = de_dy(k+1,j+1,i+1) |
---|
1045 | de_dzi(num_gp) = de_dz(k+1,j+1,i+1) |
---|
1046 | ENDIF |
---|
1047 | |
---|
1048 | ! |
---|
1049 | !-- If wall between gridpoint 3 and gridpoint 4, then |
---|
1050 | !-- Neumann boundary condition has to be applied |
---|
1051 | IF ( gp_outside_of_building(3) == 1 .AND. & |
---|
1052 | gp_outside_of_building(4) == 0 ) THEN |
---|
1053 | num_gp = num_gp + 1 |
---|
1054 | location(num_gp,1) = i * dx |
---|
1055 | location(num_gp,2) = j * dy + 0.5_wp * dy |
---|
1056 | location(num_gp,3) = k * dz + 0.5_wp * dz |
---|
1057 | ei(num_gp) = e(k+1,j,i) |
---|
1058 | dissi(num_gp) = diss(k+1,j,i) |
---|
1059 | de_dxi(num_gp) = de_dx(k+1,j,i) |
---|
1060 | de_dyi(num_gp) = 0.0_wp |
---|
1061 | de_dzi(num_gp) = de_dz(k+1,j,i) |
---|
1062 | ENDIF |
---|
1063 | |
---|
1064 | IF ( gp_outside_of_building(4) == 1 .AND. & |
---|
1065 | gp_outside_of_building(3) == 0 ) THEN |
---|
1066 | num_gp = num_gp + 1 |
---|
1067 | location(num_gp,1) = i * dx |
---|
1068 | location(num_gp,2) = j * dy + 0.5_wp * dy |
---|
1069 | location(num_gp,3) = k * dz + 0.5_wp * dz |
---|
1070 | ei(num_gp) = e(k+1,j+1,i) |
---|
1071 | dissi(num_gp) = diss(k+1,j+1,i) |
---|
1072 | de_dxi(num_gp) = de_dx(k+1,j+1,i) |
---|
1073 | de_dyi(num_gp) = 0.0_wp |
---|
1074 | de_dzi(num_gp) = de_dz(k+1,j+1,i) |
---|
1075 | ENDIF |
---|
1076 | |
---|
1077 | ! |
---|
1078 | !-- If wall between gridpoint 1 and gridpoint 3, then |
---|
1079 | !-- Neumann boundary condition has to be applied |
---|
1080 | !-- (only one case as only building beneath is possible) |
---|
1081 | IF ( gp_outside_of_building(1) == 0 .AND. & |
---|
1082 | gp_outside_of_building(3) == 1 ) THEN |
---|
1083 | num_gp = num_gp + 1 |
---|
1084 | location(num_gp,1) = i * dx |
---|
1085 | location(num_gp,2) = j * dy |
---|
1086 | location(num_gp,3) = k * dz |
---|
1087 | ei(num_gp) = e(k+1,j,i) |
---|
1088 | dissi(num_gp) = diss(k+1,j,i) |
---|
1089 | de_dxi(num_gp) = de_dx(k+1,j,i) |
---|
1090 | de_dyi(num_gp) = de_dy(k+1,j,i) |
---|
1091 | de_dzi(num_gp) = 0.0_wp |
---|
1092 | ENDIF |
---|
1093 | |
---|
1094 | ! |
---|
1095 | !-- If wall between gridpoint 5 and gridpoint 7, then |
---|
1096 | !-- Neumann boundary condition has to be applied |
---|
1097 | !-- (only one case as only building beneath is possible) |
---|
1098 | IF ( gp_outside_of_building(5) == 0 .AND. & |
---|
1099 | gp_outside_of_building(7) == 1 ) THEN |
---|
1100 | num_gp = num_gp + 1 |
---|
1101 | location(num_gp,1) = (i+1) * dx |
---|
1102 | location(num_gp,2) = j * dy |
---|
1103 | location(num_gp,3) = k * dz |
---|
1104 | ei(num_gp) = e(k+1,j,i+1) |
---|
1105 | dissi(num_gp) = diss(k+1,j,i+1) |
---|
1106 | de_dxi(num_gp) = de_dx(k+1,j,i+1) |
---|
1107 | de_dyi(num_gp) = de_dy(k+1,j,i+1) |
---|
1108 | de_dzi(num_gp) = 0.0_wp |
---|
1109 | ENDIF |
---|
1110 | |
---|
1111 | ! |
---|
1112 | !-- If wall between gridpoint 2 and gridpoint 4, then |
---|
1113 | !-- Neumann boundary condition has to be applied |
---|
1114 | !-- (only one case as only building beneath is possible) |
---|
1115 | IF ( gp_outside_of_building(2) == 0 .AND. & |
---|
1116 | gp_outside_of_building(4) == 1 ) THEN |
---|
1117 | num_gp = num_gp + 1 |
---|
1118 | location(num_gp,1) = i * dx |
---|
1119 | location(num_gp,2) = (j+1) * dy |
---|
1120 | location(num_gp,3) = k * dz |
---|
1121 | ei(num_gp) = e(k+1,j+1,i) |
---|
1122 | dissi(num_gp) = diss(k+1,j+1,i) |
---|
1123 | de_dxi(num_gp) = de_dx(k+1,j+1,i) |
---|
1124 | de_dyi(num_gp) = de_dy(k+1,j+1,i) |
---|
1125 | de_dzi(num_gp) = 0.0_wp |
---|
1126 | ENDIF |
---|
1127 | |
---|
1128 | ! |
---|
1129 | !-- If wall between gridpoint 6 and gridpoint 8, then |
---|
1130 | !-- Neumann boundary condition has to be applied |
---|
1131 | !-- (only one case as only building beneath is possible) |
---|
1132 | IF ( gp_outside_of_building(6) == 0 .AND. & |
---|
1133 | gp_outside_of_building(8) == 1 ) THEN |
---|
1134 | num_gp = num_gp + 1 |
---|
1135 | location(num_gp,1) = (i+1) * dx |
---|
1136 | location(num_gp,2) = (j+1) * dy |
---|
1137 | location(num_gp,3) = k * dz |
---|
1138 | ei(num_gp) = e(k+1,j+1,i+1) |
---|
1139 | dissi(num_gp) = diss(k+1,j+1,i+1) |
---|
1140 | de_dxi(num_gp) = de_dx(k+1,j+1,i+1) |
---|
1141 | de_dyi(num_gp) = de_dy(k+1,j+1,i+1) |
---|
1142 | de_dzi(num_gp) = 0.0_wp |
---|
1143 | ENDIF |
---|
1144 | |
---|
1145 | ! |
---|
1146 | !-- Carry out the interpolation |
---|
1147 | IF ( num_gp == 1 ) THEN |
---|
1148 | ! |
---|
1149 | !-- If only one of the gridpoints is situated outside of the |
---|
1150 | !-- building, it follows that the values at the particle |
---|
1151 | !-- location are the same as the gridpoint values |
---|
1152 | e_int(n) = ei(num_gp) |
---|
1153 | diss_int(n) = dissi(num_gp) |
---|
1154 | de_dx_int(n) = de_dxi(num_gp) |
---|
1155 | de_dy_int(n) = de_dyi(num_gp) |
---|
1156 | de_dz_int(n) = de_dzi(num_gp) |
---|
1157 | ! |
---|
1158 | !-- Set flag for stochastic equation which disables calculation |
---|
1159 | !-- of drift and memory term near topography. |
---|
1160 | term_1_2(n) = 0.0_wp |
---|
1161 | ELSE IF ( num_gp > 1 ) THEN |
---|
1162 | |
---|
1163 | d_sum = 0.0_wp |
---|
1164 | ! |
---|
1165 | !-- Evaluation of the distances between the gridpoints |
---|
1166 | !-- contributing to the interpolated values, and the particle |
---|
1167 | !-- location |
---|
1168 | DO agp = 1, num_gp |
---|
1169 | d_gp_pl(agp) = ( particles(n)%x-location(agp,1) )**2 & |
---|
1170 | + ( particles(n)%y-location(agp,2) )**2 & |
---|
1171 | + ( zv(n)-location(agp,3) )**2 |
---|
1172 | d_sum = d_sum + d_gp_pl(agp) |
---|
1173 | ENDDO |
---|
1174 | |
---|
1175 | ! |
---|
1176 | !-- Finally the interpolation can be carried out |
---|
1177 | e_int(n) = 0.0_wp |
---|
1178 | diss_int(n) = 0.0_wp |
---|
1179 | de_dx_int(n) = 0.0_wp |
---|
1180 | de_dy_int(n) = 0.0_wp |
---|
1181 | de_dz_int(n) = 0.0_wp |
---|
1182 | DO agp = 1, num_gp |
---|
1183 | e_int(n) = e_int(n) + ( d_sum - d_gp_pl(agp) ) * & |
---|
1184 | ei(agp) / ( (num_gp-1) * d_sum ) |
---|
1185 | diss_int(n) = diss_int(n) + ( d_sum - d_gp_pl(agp) ) * & |
---|
1186 | dissi(agp) / ( (num_gp-1) * d_sum ) |
---|
1187 | de_dx_int(n) = de_dx_int(n) + ( d_sum - d_gp_pl(agp) ) * & |
---|
1188 | de_dxi(agp) / ( (num_gp-1) * d_sum ) |
---|
1189 | de_dy_int(n) = de_dy_int(n) + ( d_sum - d_gp_pl(agp) ) * & |
---|
1190 | de_dyi(agp) / ( (num_gp-1) * d_sum ) |
---|
1191 | de_dz_int(n) = de_dz_int(n) + ( d_sum - d_gp_pl(agp) ) * & |
---|
1192 | de_dzi(agp) / ( (num_gp-1) * d_sum ) |
---|
1193 | ENDDO |
---|
1194 | |
---|
1195 | ENDIF |
---|
1196 | e_int(n) = MAX( 1E-20_wp, e_int(n) ) |
---|
1197 | diss_int(n) = MAX( 1E-20_wp, diss_int(n) ) |
---|
1198 | de_dx_int(n) = MAX( 1E-20_wp, de_dx_int(n) ) |
---|
1199 | de_dy_int(n) = MAX( 1E-20_wp, de_dy_int(n) ) |
---|
1200 | de_dz_int(n) = MAX( 1E-20_wp, de_dz_int(n) ) |
---|
1201 | ! |
---|
1202 | !-- Set flag for stochastic equation which disables calculation |
---|
1203 | !-- of drift and memory term near topography. |
---|
1204 | term_1_2(n) = 0.0_wp |
---|
1205 | ENDIF |
---|
1206 | ENDDO |
---|
1207 | ENDIF |
---|
1208 | |
---|
1209 | DO nb = 0,7 |
---|
1210 | i = ip + block_offset(nb)%i_off |
---|
1211 | j = jp + block_offset(nb)%j_off |
---|
1212 | k = kp + block_offset(nb)%k_off |
---|
1213 | |
---|
1214 | DO n = start_index(nb), end_index(nb) |
---|
1215 | ! |
---|
1216 | !-- Vertical interpolation of the horizontally averaged SGS TKE and |
---|
1217 | !-- resolved-scale velocity variances and use the interpolated values |
---|
1218 | !-- to calculate the coefficient fs, which is a measure of the ratio |
---|
1219 | !-- of the subgrid-scale turbulent kinetic energy to the total amount |
---|
1220 | !-- of turbulent kinetic energy. |
---|
1221 | IF ( k == 0 ) THEN |
---|
1222 | e_mean_int = hom(0,1,8,0) |
---|
1223 | ELSE |
---|
1224 | e_mean_int = hom(k,1,8,0) + & |
---|
1225 | ( hom(k+1,1,8,0) - hom(k,1,8,0) ) / & |
---|
1226 | ( zu(k+1) - zu(k) ) * & |
---|
1227 | ( zv(n) - zu(k) ) |
---|
1228 | ENDIF |
---|
1229 | |
---|
1230 | kw = kp - 1 |
---|
1231 | |
---|
1232 | IF ( k == 0 ) THEN |
---|
1233 | aa = hom(k+1,1,30,0) * ( zv(n) / & |
---|
1234 | ( 0.5_wp * ( zu(k+1) - zu(k) ) ) ) |
---|
1235 | bb = hom(k+1,1,31,0) * ( zv(n) / & |
---|
1236 | ( 0.5_wp * ( zu(k+1) - zu(k) ) ) ) |
---|
1237 | cc = hom(kw+1,1,32,0) * ( zv(n) / & |
---|
1238 | ( 1.0_wp * ( zw(kw+1) - zw(kw) ) ) ) |
---|
1239 | ELSE |
---|
1240 | aa = hom(k,1,30,0) + ( hom(k+1,1,30,0) - hom(k,1,30,0) ) * & |
---|
1241 | ( ( zv(n) - zu(k) ) / ( zu(k+1) - zu(k) ) ) |
---|
1242 | bb = hom(k,1,31,0) + ( hom(k+1,1,31,0) - hom(k,1,31,0) ) * & |
---|
1243 | ( ( zv(n) - zu(k) ) / ( zu(k+1) - zu(k) ) ) |
---|
1244 | cc = hom(kw,1,32,0) + ( hom(kw+1,1,32,0)-hom(kw,1,32,0) ) * & |
---|
1245 | ( ( zv(n) - zw(kw) ) / ( zw(kw+1)-zw(kw) ) ) |
---|
1246 | ENDIF |
---|
1247 | |
---|
1248 | vv_int = ( 1.0_wp / 3.0_wp ) * ( aa + bb + cc ) |
---|
1249 | ! |
---|
1250 | !-- Needed to avoid NaN particle velocities. The value of 1.0 is just |
---|
1251 | !-- an educated guess for the given case. |
---|
1252 | IF ( vv_int + ( 2.0_wp / 3.0_wp ) * e_mean_int == 0.0_wp ) THEN |
---|
1253 | fs_int(n) = 1.0_wp |
---|
1254 | ELSE |
---|
1255 | fs_int(n) = ( 2.0_wp / 3.0_wp ) * e_mean_int / & |
---|
1256 | ( vv_int + ( 2.0_wp / 3.0_wp ) * e_mean_int ) |
---|
1257 | ENDIF |
---|
1258 | |
---|
1259 | ENDDO |
---|
1260 | ENDDO |
---|
1261 | |
---|
1262 | DO n = 1, number_of_particles |
---|
1263 | |
---|
1264 | rg(n,1) = random_gauss( iran_part, 5.0_wp ) |
---|
1265 | rg(n,2) = random_gauss( iran_part, 5.0_wp ) |
---|
1266 | rg(n,3) = random_gauss( iran_part, 5.0_wp ) |
---|
1267 | |
---|
1268 | ENDDO |
---|
1269 | |
---|
1270 | DO n = 1, number_of_particles |
---|
1271 | ! |
---|
1272 | !-- Calculate the Lagrangian timescale according to Weil et al. (2004). |
---|
1273 | lagr_timescale = ( 4.0_wp * e_int(n) + 1E-20_wp ) / & |
---|
1274 | ( 3.0_wp * fs_int(n) * c_0 * diss_int(n) + 1E-20_wp ) |
---|
1275 | |
---|
1276 | ! |
---|
1277 | !-- Calculate the next particle timestep. dt_gap is the time needed to |
---|
1278 | !-- complete the current LES timestep. |
---|
1279 | dt_gap = dt_3d - particles(n)%dt_sum |
---|
1280 | dt_particle(n) = MIN( dt_3d, 0.025_wp * lagr_timescale, dt_gap ) |
---|
1281 | |
---|
1282 | ! |
---|
1283 | !-- The particle timestep should not be too small in order to prevent |
---|
1284 | !-- the number of particle timesteps of getting too large |
---|
1285 | IF ( dt_particle(n) < dt_min_part .AND. dt_min_part < dt_gap ) THEN |
---|
1286 | dt_particle(n) = dt_min_part |
---|
1287 | ENDIF |
---|
1288 | |
---|
1289 | ! |
---|
1290 | !-- Calculate the SGS velocity components |
---|
1291 | IF ( particles(n)%age == 0.0_wp ) THEN |
---|
1292 | ! |
---|
1293 | !-- For new particles the SGS components are derived from the SGS |
---|
1294 | !-- TKE. Limit the Gaussian random number to the interval |
---|
1295 | !-- [-5.0*sigma, 5.0*sigma] in order to prevent the SGS velocities |
---|
1296 | !-- from becoming unrealistically large. |
---|
1297 | particles(n)%rvar1 = SQRT( 2.0_wp * sgs_wf_part * e_int(n) + 1E-20_wp ) * & |
---|
1298 | ( rg(n,1) - 1.0_wp ) |
---|
1299 | particles(n)%rvar2 = SQRT( 2.0_wp * sgs_wf_part * e_int(n) + 1E-20_wp ) * & |
---|
1300 | ( rg(n,2) - 1.0_wp ) |
---|
1301 | particles(n)%rvar3 = SQRT( 2.0_wp * sgs_wf_part * e_int(n) + 1E-20_wp ) * & |
---|
1302 | ( rg(n,3) - 1.0_wp ) |
---|
1303 | |
---|
1304 | ELSE |
---|
1305 | ! |
---|
1306 | !-- Restriction of the size of the new timestep: compared to the |
---|
1307 | !-- previous timestep the increase must not exceed 200% |
---|
1308 | |
---|
1309 | dt_particle_m = particles(n)%age - particles(n)%age_m |
---|
1310 | IF ( dt_particle(n) > 2.0_wp * dt_particle_m ) THEN |
---|
1311 | dt_particle(n) = 2.0_wp * dt_particle_m |
---|
1312 | ENDIF |
---|
1313 | |
---|
1314 | ! |
---|
1315 | !-- For old particles the SGS components are correlated with the |
---|
1316 | !-- values from the previous timestep. Random numbers have also to |
---|
1317 | !-- be limited (see above). |
---|
1318 | !-- As negative values for the subgrid TKE are not allowed, the |
---|
1319 | !-- change of the subgrid TKE with time cannot be smaller than |
---|
1320 | !-- -e_int(n)/dt_particle. This value is used as a lower boundary |
---|
1321 | !-- value for the change of TKE |
---|
1322 | |
---|
1323 | de_dt_min = - e_int(n) / dt_particle(n) |
---|
1324 | |
---|
1325 | de_dt = ( e_int(n) - particles(n)%e_m ) / dt_particle_m |
---|
1326 | |
---|
1327 | IF ( de_dt < de_dt_min ) THEN |
---|
1328 | de_dt = de_dt_min |
---|
1329 | ENDIF |
---|
1330 | |
---|
1331 | CALL weil_stochastic_eq(particles(n)%rvar1, fs_int(n), e_int(n), & |
---|
1332 | de_dx_int(n), de_dt, diss_int(n), & |
---|
1333 | dt_particle(n), rg(n,1), term_1_2(n) ) |
---|
1334 | |
---|
1335 | CALL weil_stochastic_eq(particles(n)%rvar2, fs_int(n), e_int(n), & |
---|
1336 | de_dy_int(n), de_dt, diss_int(n), & |
---|
1337 | dt_particle(n), rg(n,2), term_1_2(n) ) |
---|
1338 | |
---|
1339 | CALL weil_stochastic_eq(particles(n)%rvar3, fs_int(n), e_int(n), & |
---|
1340 | de_dz_int(n), de_dt, diss_int(n), & |
---|
1341 | dt_particle(n), rg(n,3), term_1_2(n) ) |
---|
1342 | |
---|
1343 | ENDIF |
---|
1344 | |
---|
1345 | u_int(n) = u_int(n) + particles(n)%rvar1 |
---|
1346 | v_int(n) = v_int(n) + particles(n)%rvar2 |
---|
1347 | w_int(n) = w_int(n) + particles(n)%rvar3 |
---|
1348 | ! |
---|
1349 | !-- Store the SGS TKE of the current timelevel which is needed for |
---|
1350 | !-- for calculating the SGS particle velocities at the next timestep |
---|
1351 | particles(n)%e_m = e_int(n) |
---|
1352 | ENDDO |
---|
1353 | |
---|
1354 | ELSE |
---|
1355 | ! |
---|
1356 | !-- If no SGS velocities are used, only the particle timestep has to |
---|
1357 | !-- be set |
---|
1358 | dt_particle = dt_3d |
---|
1359 | |
---|
1360 | ENDIF |
---|
1361 | ! |
---|
1362 | !-- Store the old age of the particle ( needed to prevent that a |
---|
1363 | !-- particle crosses several PEs during one timestep, and for the |
---|
1364 | !-- evaluation of the subgrid particle velocity fluctuations ) |
---|
1365 | particles(1:number_of_particles)%age_m = particles(1:number_of_particles)%age |
---|
1366 | |
---|
1367 | dens_ratio = particle_groups(particles(1:number_of_particles)%group)%density_ratio |
---|
1368 | |
---|
1369 | IF ( ANY( dens_ratio == 0.0_wp ) ) THEN |
---|
1370 | DO n = 1, number_of_particles |
---|
1371 | |
---|
1372 | ! |
---|
1373 | !-- Particle advection |
---|
1374 | IF ( dens_ratio(n) == 0.0_wp ) THEN |
---|
1375 | ! |
---|
1376 | !-- Pure passive transport (without particle inertia) |
---|
1377 | particles(n)%x = xv(n) + u_int(n) * dt_particle(n) |
---|
1378 | particles(n)%y = yv(n) + v_int(n) * dt_particle(n) |
---|
1379 | particles(n)%z = zv(n) + w_int(n) * dt_particle(n) |
---|
1380 | |
---|
1381 | particles(n)%speed_x = u_int(n) |
---|
1382 | particles(n)%speed_y = v_int(n) |
---|
1383 | particles(n)%speed_z = w_int(n) |
---|
1384 | |
---|
1385 | ELSE |
---|
1386 | ! |
---|
1387 | !-- Transport of particles with inertia |
---|
1388 | particles(n)%x = particles(n)%x + particles(n)%speed_x * & |
---|
1389 | dt_particle(n) |
---|
1390 | particles(n)%y = particles(n)%y + particles(n)%speed_y * & |
---|
1391 | dt_particle(n) |
---|
1392 | particles(n)%z = particles(n)%z + particles(n)%speed_z * & |
---|
1393 | dt_particle(n) |
---|
1394 | |
---|
1395 | ! |
---|
1396 | !-- Update of the particle velocity |
---|
1397 | IF ( cloud_droplets ) THEN |
---|
1398 | ! |
---|
1399 | !-- Terminal velocity is computed for vertical direction (Rogers et |
---|
1400 | !-- al., 1993, J. Appl. Meteorol.) |
---|
1401 | diameter = particles(n)%radius * 2000.0_wp !diameter in mm |
---|
1402 | IF ( diameter <= d0_rog ) THEN |
---|
1403 | w_s = k_cap_rog * diameter * ( 1.0_wp - EXP( -k_low_rog * diameter ) ) |
---|
1404 | ELSE |
---|
1405 | w_s = a_rog - b_rog * EXP( -c_rog * diameter ) |
---|
1406 | ENDIF |
---|
1407 | |
---|
1408 | ! |
---|
1409 | !-- If selected, add random velocities following Soelch and Kaercher |
---|
1410 | !-- (2010, Q. J. R. Meteorol. Soc.) |
---|
1411 | IF ( use_sgs_for_particles ) THEN |
---|
1412 | lagr_timescale = km(kp,jp,ip) / MAX( e(kp,jp,ip), 1.0E-20_wp ) |
---|
1413 | RL = EXP( -1.0_wp * dt_3d / lagr_timescale ) |
---|
1414 | sigma = SQRT( e(kp,jp,ip) ) |
---|
1415 | |
---|
1416 | rg1 = random_gauss( iran_part, 5.0_wp ) - 1.0_wp |
---|
1417 | rg2 = random_gauss( iran_part, 5.0_wp ) - 1.0_wp |
---|
1418 | rg3 = random_gauss( iran_part, 5.0_wp ) - 1.0_wp |
---|
1419 | |
---|
1420 | particles(n)%rvar1 = RL * particles(n)%rvar1 + & |
---|
1421 | SQRT( 1.0_wp - RL**2 ) * sigma * rg1 |
---|
1422 | particles(n)%rvar2 = RL * particles(n)%rvar2 + & |
---|
1423 | SQRT( 1.0_wp - RL**2 ) * sigma * rg2 |
---|
1424 | particles(n)%rvar3 = RL * particles(n)%rvar3 + & |
---|
1425 | SQRT( 1.0_wp - RL**2 ) * sigma * rg3 |
---|
1426 | |
---|
1427 | particles(n)%speed_x = u_int(n) + particles(n)%rvar1 |
---|
1428 | particles(n)%speed_y = v_int(n) + particles(n)%rvar2 |
---|
1429 | particles(n)%speed_z = w_int(n) + particles(n)%rvar3 - w_s |
---|
1430 | ELSE |
---|
1431 | particles(n)%speed_x = u_int(n) |
---|
1432 | particles(n)%speed_y = v_int(n) |
---|
1433 | particles(n)%speed_z = w_int(n) - w_s |
---|
1434 | ENDIF |
---|
1435 | |
---|
1436 | ELSE |
---|
1437 | |
---|
1438 | IF ( use_sgs_for_particles ) THEN |
---|
1439 | exp_arg = particle_groups(particles(n)%group)%exp_arg |
---|
1440 | exp_term = EXP( -exp_arg * dt_particle(n) ) |
---|
1441 | ELSE |
---|
1442 | exp_arg = particle_groups(particles(n)%group)%exp_arg |
---|
1443 | exp_term = particle_groups(particles(n)%group)%exp_term |
---|
1444 | ENDIF |
---|
1445 | particles(n)%speed_x = particles(n)%speed_x * exp_term + & |
---|
1446 | u_int(n) * ( 1.0_wp - exp_term ) |
---|
1447 | particles(n)%speed_y = particles(n)%speed_y * exp_term + & |
---|
1448 | v_int(n) * ( 1.0_wp - exp_term ) |
---|
1449 | particles(n)%speed_z = particles(n)%speed_z * exp_term + & |
---|
1450 | ( w_int(n) - ( 1.0_wp - dens_ratio(n) ) * & |
---|
1451 | g / exp_arg ) * ( 1.0_wp - exp_term ) |
---|
1452 | ENDIF |
---|
1453 | |
---|
1454 | ENDIF |
---|
1455 | |
---|
1456 | ENDDO |
---|
1457 | |
---|
1458 | ELSE |
---|
1459 | |
---|
1460 | DO n = 1, number_of_particles |
---|
1461 | |
---|
1462 | !-- Transport of particles with inertia |
---|
1463 | particles(n)%x = xv(n) + particles(n)%speed_x * dt_particle(n) |
---|
1464 | particles(n)%y = yv(n) + particles(n)%speed_y * dt_particle(n) |
---|
1465 | particles(n)%z = zv(n) + particles(n)%speed_z * dt_particle(n) |
---|
1466 | ! |
---|
1467 | !-- Update of the particle velocity |
---|
1468 | IF ( cloud_droplets ) THEN |
---|
1469 | ! |
---|
1470 | !-- Terminal velocity is computed for vertical direction (Rogers et al., |
---|
1471 | !-- 1993, J. Appl. Meteorol.) |
---|
1472 | diameter = particles(n)%radius * 2000.0_wp !diameter in mm |
---|
1473 | IF ( diameter <= d0_rog ) THEN |
---|
1474 | w_s = k_cap_rog * diameter * ( 1.0_wp - EXP( -k_low_rog * diameter ) ) |
---|
1475 | ELSE |
---|
1476 | w_s = a_rog - b_rog * EXP( -c_rog * diameter ) |
---|
1477 | ENDIF |
---|
1478 | |
---|
1479 | ! |
---|
1480 | !-- If selected, add random velocities following Soelch and Kaercher |
---|
1481 | !-- (2010, Q. J. R. Meteorol. Soc.) |
---|
1482 | IF ( use_sgs_for_particles ) THEN |
---|
1483 | lagr_timescale = km(kp,jp,ip) / MAX( e(kp,jp,ip), 1.0E-20_wp ) |
---|
1484 | RL = EXP( -1.0_wp * dt_3d / lagr_timescale ) |
---|
1485 | sigma = SQRT( e(kp,jp,ip) ) |
---|
1486 | |
---|
1487 | rg1 = random_gauss( iran_part, 5.0_wp ) - 1.0_wp |
---|
1488 | rg2 = random_gauss( iran_part, 5.0_wp ) - 1.0_wp |
---|
1489 | rg3 = random_gauss( iran_part, 5.0_wp ) - 1.0_wp |
---|
1490 | |
---|
1491 | particles(n)%rvar1 = RL * particles(n)%rvar1 + & |
---|
1492 | SQRT( 1.0_wp - RL**2 ) * sigma * rg1 |
---|
1493 | particles(n)%rvar2 = RL * particles(n)%rvar2 + & |
---|
1494 | SQRT( 1.0_wp - RL**2 ) * sigma * rg2 |
---|
1495 | particles(n)%rvar3 = RL * particles(n)%rvar3 + & |
---|
1496 | SQRT( 1.0_wp - RL**2 ) * sigma * rg3 |
---|
1497 | |
---|
1498 | particles(n)%speed_x = u_int(n) + particles(n)%rvar1 |
---|
1499 | particles(n)%speed_y = v_int(n) + particles(n)%rvar2 |
---|
1500 | particles(n)%speed_z = w_int(n) + particles(n)%rvar3 - w_s |
---|
1501 | ELSE |
---|
1502 | particles(n)%speed_x = u_int(n) |
---|
1503 | particles(n)%speed_y = v_int(n) |
---|
1504 | particles(n)%speed_z = w_int(n) - w_s |
---|
1505 | ENDIF |
---|
1506 | |
---|
1507 | ELSE |
---|
1508 | |
---|
1509 | IF ( use_sgs_for_particles ) THEN |
---|
1510 | exp_arg = particle_groups(particles(n)%group)%exp_arg |
---|
1511 | exp_term = EXP( -exp_arg * dt_particle(n) ) |
---|
1512 | ELSE |
---|
1513 | exp_arg = particle_groups(particles(n)%group)%exp_arg |
---|
1514 | exp_term = particle_groups(particles(n)%group)%exp_term |
---|
1515 | ENDIF |
---|
1516 | particles(n)%speed_x = particles(n)%speed_x * exp_term + & |
---|
1517 | u_int(n) * ( 1.0_wp - exp_term ) |
---|
1518 | particles(n)%speed_y = particles(n)%speed_y * exp_term + & |
---|
1519 | v_int(n) * ( 1.0_wp - exp_term ) |
---|
1520 | particles(n)%speed_z = particles(n)%speed_z * exp_term + & |
---|
1521 | ( w_int(n) - ( 1.0_wp - dens_ratio(n) ) * g / & |
---|
1522 | exp_arg ) * ( 1.0_wp - exp_term ) |
---|
1523 | ENDIF |
---|
1524 | |
---|
1525 | ENDDO |
---|
1526 | |
---|
1527 | ENDIF |
---|
1528 | |
---|
1529 | DO n = 1, number_of_particles |
---|
1530 | ! |
---|
1531 | !-- Increment the particle age and the total time that the particle |
---|
1532 | !-- has advanced within the particle timestep procedure |
---|
1533 | particles(n)%age = particles(n)%age + dt_particle(n) |
---|
1534 | particles(n)%dt_sum = particles(n)%dt_sum + dt_particle(n) |
---|
1535 | |
---|
1536 | ! |
---|
1537 | !-- Check whether there is still a particle that has not yet completed |
---|
1538 | !-- the total LES timestep |
---|
1539 | IF ( ( dt_3d - particles(n)%dt_sum ) > 1E-8_wp ) THEN |
---|
1540 | dt_3d_reached_l = .FALSE. |
---|
1541 | ENDIF |
---|
1542 | |
---|
1543 | ENDDO |
---|
1544 | |
---|
1545 | CALL cpu_log( log_point_s(44), 'lpm_advec', 'pause' ) |
---|
1546 | |
---|
1547 | |
---|
1548 | END SUBROUTINE lpm_advec |
---|
1549 | |
---|
1550 | ! Description: |
---|
1551 | ! ------------ |
---|
1552 | !> Calculation of subgrid-scale particle speed using the stochastic model |
---|
1553 | !> of Weil et al. (2004, JAS, 61, 2877-2887). |
---|
1554 | !------------------------------------------------------------------------------! |
---|
1555 | SUBROUTINE weil_stochastic_eq( v_sgs, fs_n, e_n, dedxi_n, dedt_n, diss_n, & |
---|
1556 | dt_n, rg_n, fac ) |
---|
1557 | |
---|
1558 | USE kinds |
---|
1559 | |
---|
1560 | USE particle_attributes, & |
---|
1561 | ONLY: c_0, sgs_wf_part |
---|
1562 | |
---|
1563 | IMPLICIT NONE |
---|
1564 | |
---|
1565 | REAL(wp) :: a1 !< dummy argument |
---|
1566 | REAL(wp) :: dedt_n !< time derivative of TKE at particle position |
---|
1567 | REAL(wp) :: dedxi_n !< horizontal derivative of TKE at particle position |
---|
1568 | REAL(wp) :: diss_n !< dissipation at particle position |
---|
1569 | REAL(wp) :: dt_n !< particle timestep |
---|
1570 | REAL(wp) :: e_n !< TKE at particle position |
---|
1571 | REAL(wp) :: fac !< flag to identify adjacent topography |
---|
1572 | REAL(wp) :: fs_n !< weighting factor to prevent that subgrid-scale particle speed becomes too large |
---|
1573 | REAL(wp) :: sgs_w !< constant (1/3) |
---|
1574 | REAL(wp) :: rg_n !< random number |
---|
1575 | REAL(wp) :: term1 !< memory term |
---|
1576 | REAL(wp) :: term2 !< drift correction term |
---|
1577 | REAL(wp) :: term3 !< random term |
---|
1578 | REAL(wp) :: v_sgs !< subgrid-scale velocity component |
---|
1579 | |
---|
1580 | ! |
---|
1581 | !-- Please note, terms 1 and 2 (drift and memory term, respectively) are |
---|
1582 | !-- multiplied by a flag to switch of both terms near topography. |
---|
1583 | !-- This is necessary, as both terms may cause a subgrid-scale velocity build up |
---|
1584 | !-- if particles are trapped in regions with very small TKE, e.g. in narrow street |
---|
1585 | !-- canyons resolved by only a few grid points. Hence, term 1 and term 2 are |
---|
1586 | !-- disabled if one of the adjacent grid points belongs to topography. |
---|
1587 | !-- Moreover, in this case, the previous subgrid-scale component is also set |
---|
1588 | !-- to zero. |
---|
1589 | |
---|
1590 | a1 = fs_n * c_0 * diss_n |
---|
1591 | ! |
---|
1592 | !-- Memory term |
---|
1593 | term1 = - a1 * v_sgs * dt_n / ( 4.0_wp * sgs_wf_part * e_n + 1E-20_wp ) & |
---|
1594 | * fac |
---|
1595 | ! |
---|
1596 | !-- Drift correction term |
---|
1597 | term2 = ( ( dedt_n * v_sgs / e_n ) + dedxi_n ) * 0.5_wp * dt_n & |
---|
1598 | * fac |
---|
1599 | ! |
---|
1600 | !-- Random term |
---|
1601 | term3 = SQRT( MAX( a1, 1E-20 ) ) * ( rg_n - 1.0_wp ) * SQRT( dt_n ) |
---|
1602 | ! |
---|
1603 | !-- In cese one of the adjacent grid-boxes belongs to topograhy, the previous |
---|
1604 | !-- subgrid-scale velocity component is set to zero, in order to prevent a |
---|
1605 | !-- velocity build-up. |
---|
1606 | |
---|
1607 | !-- This case, set also previous subgrid-scale component to zero. |
---|
1608 | v_sgs = v_sgs * fac + term1 + term2 + term3 |
---|
1609 | |
---|
1610 | END SUBROUTINE weil_stochastic_eq |
---|