1 | MODULE etat0_jablonowsky06_mod |
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2 | USE genmod |
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3 | PRIVATE |
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4 | REAL(rstd),PARAMETER :: eta0=0.252 |
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5 | REAL(rstd),PARAMETER :: etat=0.2 |
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6 | REAL(rstd),PARAMETER :: ps0=1e5 |
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7 | REAL(rstd),PARAMETER :: u0=35 |
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8 | ! REAL(rstd),PARAMETER :: u0=0 |
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9 | REAL(rstd),PARAMETER :: T0=288 |
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10 | REAL(rstd),PARAMETER :: DeltaT=4.8e5 |
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11 | REAL(rstd),PARAMETER :: Rd=287 |
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12 | REAL(rstd),PARAMETER :: Gamma=0.005 |
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13 | REAL(rstd),PARAMETER :: up0=1 |
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14 | PUBLIC test_etat0_jablonowsky06, etat0_jablonowsky06, compute_etat0_jablonowsky06 |
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15 | CONTAINS |
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16 | |
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17 | SUBROUTINE test_etat0_jablonowsky06 |
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18 | USE field_mod |
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19 | USE domain_mod |
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20 | USE dimensions |
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21 | USE grid_param |
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22 | USE geometry |
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23 | USE write_field |
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24 | USE kinetic_mod |
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25 | USE pression_mod |
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26 | USE exner_mod |
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27 | USE geopotential_mod |
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28 | USE vorticity_mod |
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29 | IMPLICIT NONE |
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30 | TYPE(t_field),POINTER :: f_ps(:) |
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31 | TYPE(t_field),POINTER :: f_phis(:) |
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32 | TYPE(t_field),POINTER :: f_theta_rhodz(:) |
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33 | TYPE(t_field),POINTER :: f_u(:) |
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34 | TYPE(t_field),POINTER :: f_Ki(:) |
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35 | TYPE(t_field),POINTER :: f_temp(:) |
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36 | TYPE(t_field),POINTER :: f_p(:) |
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37 | TYPE(t_field),POINTER :: f_pks(:) |
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38 | TYPE(t_field),POINTER :: f_pk(:) |
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39 | TYPE(t_field),POINTER :: f_phi(:) |
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40 | TYPE(t_field),POINTER :: f_vort(:) |
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41 | |
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42 | REAL(rstd),POINTER :: Ki(:,:) |
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43 | REAL(rstd),POINTER :: temp(:) |
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44 | INTEGER :: ind |
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45 | |
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46 | |
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47 | CALL allocate_field(f_ps,field_t,type_real) |
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48 | CALL allocate_field(f_phis,field_t,type_real) |
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49 | CALL allocate_field(f_theta_rhodz,field_t,type_real,llm) |
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50 | CALL allocate_field(f_u,field_u,type_real,llm) |
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51 | CALL allocate_field(f_p,field_t,type_real,llm+1) |
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52 | CALL allocate_field(f_Ki,field_t,type_real,llm) |
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53 | CALL allocate_field(f_pks,field_t,type_real) |
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54 | CALL allocate_field(f_pk,field_t,type_real,llm) |
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55 | CALL allocate_field(f_phi,field_t,type_real,llm) |
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56 | CALL allocate_field(f_temp,field_t,type_real) |
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57 | CALL allocate_field(f_vort,field_z,type_real,llm) |
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58 | |
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59 | CALL etat0_jablonowsky06(f_ps,f_phis,f_theta_rhodz,f_u) |
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60 | |
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61 | CALL kinetic(f_u,f_Ki) |
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62 | CALL vorticity(f_u,f_vort) |
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63 | |
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64 | CALL pression(f_ps,f_p) |
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65 | CALL exner(f_ps,f_p,f_pks,f_pk) |
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66 | CALL geopotential(f_phis,f_pks,f_pk,f_theta_rhodz,f_phi) |
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67 | |
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68 | CALL writefield('ps',f_ps) |
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69 | CALL writefield('phis',f_phis) |
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70 | CALL writefield('theta',f_theta_rhodz) |
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71 | CALL writefield('f_phi',f_phi) |
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72 | |
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73 | CALL writefield('Ki',f_Ki) |
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74 | CALL writefield('vort',f_vort) |
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75 | |
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76 | END SUBROUTINE test_etat0_jablonowsky06 |
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77 | |
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78 | |
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79 | SUBROUTINE etat0_jablonowsky06(f_ps,f_phis,f_theta_rhodz,f_u) |
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80 | USE field_mod |
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81 | USE domain_mod |
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82 | USE domain_mod |
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83 | USE dimensions |
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84 | USE grid_param |
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85 | USE geometry |
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86 | IMPLICIT NONE |
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87 | TYPE(t_field),POINTER :: f_ps(:) |
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88 | TYPE(t_field),POINTER :: f_phis(:) |
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89 | TYPE(t_field),POINTER :: f_theta_rhodz(:) |
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90 | TYPE(t_field),POINTER :: f_u(:) |
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91 | |
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92 | REAL(rstd),POINTER :: ps(:) |
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93 | REAL(rstd),POINTER :: phis(:) |
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94 | REAL(rstd),POINTER :: theta_rhodz(:,:) |
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95 | REAL(rstd),POINTER :: u(:,:) |
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96 | INTEGER :: ind |
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97 | |
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98 | DO ind=1,ndomain |
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99 | CALL swap_dimensions(ind) |
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100 | CALL swap_geometry(ind) |
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101 | ps=f_ps(ind) |
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102 | phis=f_phis(ind) |
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103 | theta_rhodz=f_theta_rhodz(ind) |
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104 | u=f_u(ind) |
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105 | CALL compute_etat0_jablonowsky06(ps, phis, theta_rhodz, u) |
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106 | ENDDO |
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107 | |
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108 | END SUBROUTINE etat0_jablonowsky06 |
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109 | |
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110 | SUBROUTINE compute_etat0_jablonowsky06(ps, phis, theta_rhodz, u) |
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111 | USE domain_mod |
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112 | USE dimensions |
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113 | USE grid_param |
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114 | USE geometry |
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115 | USE metric |
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116 | USE disvert_mod |
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117 | USE spherical_geom_mod |
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118 | USE vector |
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119 | USE pression_mod |
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120 | USE exner_mod |
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121 | USE geopotential_mod |
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122 | USE theta2theta_rhodz_mod |
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123 | IMPLICIT NONE |
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124 | REAL(rstd),INTENT(OUT) :: ps(iim*jjm) |
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125 | REAL(rstd),INTENT(OUT) :: phis(iim*jjm) |
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126 | REAL(rstd),INTENT(OUT) :: theta_rhodz(iim*jjm,llm) |
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127 | REAL(rstd),INTENT(OUT) :: u(3*iim*jjm,llm) |
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128 | |
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129 | INTEGER :: i,j,l,ij |
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130 | REAL(rstd) :: theta(iim*jjm,llm) |
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131 | REAL(rstd) :: eta(llm) |
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132 | REAL(rstd) :: etav(llm) |
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133 | REAL(rstd) :: etas, etavs |
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134 | REAL(rstd) :: lon,lat |
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135 | REAL(rstd) :: ulon(3) |
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136 | REAL(rstd) :: ep(3), norm_ep |
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137 | REAL(rstd) :: Tave, T |
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138 | REAL(rstd) :: phis_ave |
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139 | REAL(rstd) :: V0(3) |
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140 | REAL(rstd) :: r2 |
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141 | REAL(rstd) :: utot |
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142 | |
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143 | DO l=1,llm |
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144 | eta(l)= 0.5 *( ap(l)/ps0+bp(l) + ap(l+1)/ps0+bp(l+1) ) |
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145 | etav(l)=(eta(l)-eta0)*Pi/2 |
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146 | ENDDO |
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147 | etas=ap(1)+bp(1) |
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148 | etavs=(etas-eta0)*Pi/2 |
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149 | |
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150 | DO j=jj_begin,jj_end |
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151 | DO i=ii_begin,ii_end |
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152 | ij=(j-1)*iim+i |
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153 | ps(ij)=ps0 |
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154 | ENDDO |
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155 | ENDDO |
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156 | |
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157 | |
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158 | CALL lonlat2xyz(Pi/9,2*Pi/9,V0) |
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159 | u(:,:)=1e10 |
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160 | DO l=1,llm |
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161 | DO j=jj_begin,jj_end |
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162 | DO i=ii_begin,ii_end |
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163 | ij=(j-1)*iim+i |
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164 | |
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165 | CALL xyz2lonlat(xyz_e(ij+u_right,:)/radius,lon,lat) |
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166 | CALL cross_product2(V0,xyz_e(ij+u_right,:)/radius,ep) |
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167 | r2=(asin(sum(ep*ep)))**2 |
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168 | utot=u0*cos(etav(l))**1.5*sin(2*lat)**2 + up0*exp(-r2/0.01) |
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169 | |
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170 | ulon(1) = -sin(lon) * utot |
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171 | ulon(2) = cos(lon) * utot |
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172 | ulon(3) = 0 * utot |
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173 | |
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174 | |
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175 | CALL cross_product2(xyz_v(ij+z_rdown,:)/radius,xyz_v(ij+z_rup,:)/radius,ep) |
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176 | norm_ep=sqrt(sum(ep(:)**2)) |
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177 | IF (norm_ep>1e-30) THEN |
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178 | ep=-ep/norm_ep*ne(ij,right) |
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179 | u(ij+u_right,l)=sum(ep(:)*ulon(:)) |
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180 | ENDIF |
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181 | |
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182 | |
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183 | |
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184 | CALL xyz2lonlat(xyz_e(ij+u_lup,:)/radius,lon,lat) |
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185 | CALL cross_product2(V0,xyz_e(ij+u_lup,:)/radius,ep) |
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186 | r2=(asin(sum(ep*ep)))**2 |
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187 | utot=u0*cos(etav(l))**1.5*sin(2*lat)**2 + up0*exp(-r2/0.01) |
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188 | ulon(1) = -sin(lon) * utot |
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189 | ulon(2) = cos(lon) * utot |
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190 | ulon(3) = 0 * utot |
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191 | |
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192 | |
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193 | CALL cross_product2(xyz_v(ij+z_up,:)/radius,xyz_v(ij+z_lup,:)/radius,ep) |
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194 | norm_ep=sqrt(sum(ep(:)**2)) |
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195 | IF (norm_ep>1e-30) THEN |
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196 | ep=-ep/norm_ep*ne(ij,lup) |
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197 | u(ij+u_lup,l)=sum(ep(:)*ulon(:)) |
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198 | ENDIF |
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199 | |
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200 | |
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201 | |
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202 | |
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203 | |
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204 | |
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205 | CALL xyz2lonlat(xyz_e(ij+u_ldown,:)/radius,lon,lat) |
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206 | CALL cross_product2(V0,xyz_e(ij+u_ldown,:)/radius,ep) |
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207 | r2=(asin(sum(ep*ep)))**2 |
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208 | utot=u0*cos(etav(l))**1.5*sin(2*lat)**2 + up0*exp(-r2/0.01) |
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209 | ulon(1) = -sin(lon) * utot |
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210 | ulon(2) = cos(lon) * utot |
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211 | ulon(3) = 0 * utot |
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212 | |
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213 | |
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214 | CALL cross_product2(xyz_v(ij+z_ldown,:)/radius,xyz_v(ij+z_down,:)/radius,ep) |
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215 | norm_ep=sqrt(sum(ep(:)**2)) |
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216 | IF (norm_ep>1e-30) THEN |
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217 | ep=-ep/norm_ep*ne(ij,ldown) |
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218 | u(ij+u_ldown,l)=sum(ep(:)*ulon(:)) |
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219 | ENDIF |
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220 | |
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221 | ENDDO |
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222 | ENDDO |
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223 | ENDDO |
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224 | |
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225 | |
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226 | DO l=1,llm |
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227 | Tave=T0*eta(l)**(Rd*Gamma/g) |
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228 | IF (etat>eta(l)) Tave=Tave+DeltaT*(etat-eta(l))**5 |
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229 | DO j=jj_begin,jj_end |
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230 | DO i=ii_begin,ii_end |
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231 | ij=(j-1)*iim+i |
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232 | CALL xyz2lonlat(xyz_i(ij,:)/radius,lon,lat) |
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233 | |
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234 | T=Tave+ 0.75*(eta(l)*Pi*u0/Rd)*sin(etav(l))*cos(etav(l))**0.5 & |
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235 | * ( (-2*sin(lat)**6*(cos(lat)**2+1./3)+10./63)*2*u0*cos(etav(l))**1.5 & |
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236 | + (8./5*cos(lat)**3*(sin(lat)**2+2./3)-Pi/4)*radius*Omega) |
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237 | |
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238 | theta(ij,l)=T*eta(l)**(-kappa) |
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239 | |
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240 | ENDDO |
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241 | ENDDO |
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242 | ENDDO |
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243 | |
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244 | |
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245 | phis_ave=T0*g/Gamma*(1-etas**(Rd*Gamma/g)) |
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246 | DO j=jj_begin,jj_end |
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247 | DO i=ii_begin,ii_end |
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248 | ij=(j-1)*iim+i |
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249 | CALL xyz2lonlat(xyz_i(ij,:)/radius,lon,lat) |
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250 | phis(ij)=phis_ave+u0*cos(etavs)**1.5*( (-2*sin(lat)**6 * (cos(lat)**2+1./3) + 10./63 )*u0*cos(etavs)**1.5 & |
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251 | +(8./5*cos(lat)**3 * (sin(lat)**2 + 2./3) - Pi/4)*radius*Omega ) |
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252 | ENDDO |
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253 | ENDDO |
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254 | |
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255 | CALL compute_theta2theta_rhodz(ps,theta,theta_rhodz,0) |
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256 | |
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257 | END SUBROUTINE compute_etat0_jablonowsky06 |
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258 | |
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259 | END MODULE etat0_jablonowsky06_mod |
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