1 | SUBROUTINE rings(ngrid, declin, ptime, rad, flat, eclipse) |
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2 | ! Calculates Saturn's rings shadowing |
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3 | ! Includes rings opacities measured by Cassini/UVIS |
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4 | ! Authors: M. Sylvestre, M. Capderou, S. Guerlet, A. Spiga |
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5 | |
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6 | use comdiurn_h, only: sinlat, sinlon, coslat, coslon |
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7 | use geometry_mod, only: latitude ! (rad) |
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8 | |
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9 | implicit none |
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10 | |
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11 | INTEGER, INTENT(IN) :: ngrid ! horizontal grid dimension |
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12 | REAL, INTENT(IN) :: declin ! latitude of the subsolar point |
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13 | REAL, INTENT(IN) :: ptime ! UTC time in sol fraction : ptime=0.5 at noon |
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14 | REAL, INTENT(IN) :: rad ! equatorial radius of the planet |
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15 | REAL, INTENT(IN) :: flat ! flattening of the planet |
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16 | REAL, DIMENSION(ngrid), INTENT(OUT) :: eclipse ! absorption of the light by the rings |
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17 | |
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18 | REAL :: rpol ! polar radius of the planet |
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19 | REAL :: e ! shape excentricity of the planet : (1-e*e) = (1-f)*(1-f) |
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20 | INTEGER, PARAMETER :: nb_a = 4 ! number of subdivisions of the A ring |
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21 | INTEGER, PARAMETER :: nb_b = 3 ! number of subdivisions of the B ring |
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22 | INTEGER, PARAMETER :: nb_c = 3 ! number of subdivisions of the C ring |
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23 | INTEGER, PARAMETER :: nb_ca = 2 ! number of subdivisions in the Cassini division |
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24 | INTEGER :: i |
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25 | |
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26 | ! arrays for the rings. TBD: dynamical? |
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27 | REAL, DIMENSION(nb_a) :: A_Rint ! internal radii of the subdivisions of the A ring |
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28 | REAL, DIMENSION(nb_a) :: A_Rext ! external radii of the subdivisions of the A ring |
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29 | REAL, DIMENSION(nb_b) :: B_Rint ! internal radii of the subdivisions of the B ring |
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30 | REAL, DIMENSION(nb_b) :: B_Rext ! external radii of the subdivisions of the B ring |
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31 | REAL, DIMENSION(nb_c) :: C_Rint ! internal radii of the subdivisions of the C ring |
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32 | REAL, DIMENSION(nb_c) :: C_Rext ! external radii of the subdivisions of the C ring |
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33 | REAL, DIMENSION(nb_ca) :: Ca_Rint ! internal radii of the subdivisions of the Cassini Division |
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34 | REAL, DIMENSION(nb_ca) :: Ca_Rext ! external radii of the subdivisions of the Cassini Division |
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35 | |
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36 | ! Opacities of the rings : for each one we can give different opacities for each part |
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37 | REAL, DIMENSION(nb_a) :: tau_A ! opacity of the A ring |
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38 | REAL, DIMENSION(nb_b) :: tau_B ! opacity of the B ring |
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39 | REAL, DIMENSION(nb_c) :: tau_C ! opacity of the C ring |
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40 | REAL, DIMENSION(nb_ca) :: tau_Ca ! opacity of the Cassini Division |
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41 | |
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42 | ! Parameters used to calculate if a point is under a ring subdivision's shadow |
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43 | REAL :: phi_S ! subsolar point longitude |
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44 | REAL, PARAMETER :: pi=acos(-1.0) |
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45 | REAL, DIMENSION(:), ALLOCATABLE:: x, y, z ! cartesian coordinates of the points on the planet |
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46 | REAL :: xs, ys, zs ! cartesian coordinates of the points of the subsolar point |
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47 | REAL, DIMENSION(:), ALLOCATABLE :: k |
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48 | REAL, DIMENSION(:), ALLOCATABLE :: N ! parameter to compute cartesian coordinates on a ellipsoidal planet |
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49 | REAL, DIMENSION(:), ALLOCATABLE :: r ! distance at which the incident ray of sun crosses the equatorial plane |
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50 | ! measured from the center of the planet |
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51 | REAL :: Ns ! (same for the subsolar point) |
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52 | |
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53 | ! equinox --> no shadow (AS: why is this needed?) |
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54 | if(declin .eq. 0.) then |
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55 | eclipse(:) = 0. |
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56 | return |
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57 | endif |
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58 | |
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59 | ! 1) INITIALIZATION |
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60 | |
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61 | ! Generic |
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62 | rpol = (1.- flat)*rad |
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63 | e = sqrt(2*flat - flat**2) |
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64 | ALLOCATE(x(ngrid)) |
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65 | ALLOCATE(y(ngrid)) |
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66 | ALLOCATE(z(ngrid)) |
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67 | ALLOCATE(k(ngrid)) |
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68 | ALLOCATE(N(ngrid)) |
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69 | ALLOCATE(r(ngrid)) |
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70 | eclipse(:) = 2000. |
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71 | |
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72 | ! Model of the rings with Cassini/UVIS opacities |
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73 | |
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74 | ! Size of the rings |
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75 | A_Rint(1) = 2.03*rad |
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76 | A_Rext(1) = 2.06*rad |
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77 | A_Rint(2) = 2.06*rad |
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78 | A_Rext(2) = 2.09*rad |
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79 | A_Rint(3) = 2.09*rad |
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80 | A_Rext(3) = 2.12*rad |
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81 | A_Rint(4) = 2.12*rad |
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82 | A_Rext(4) = 2.27*rad |
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83 | |
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84 | B_Rint(1) = 1.53*rad |
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85 | B_Rext(1) = 1.64*rad |
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86 | B_Rint(2) = 1.64*rad |
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87 | B_Rext(2) = 1.83*rad |
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88 | B_Rint(3) = 1.83*rad |
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89 | B_Rext(3) = 1.95*rad |
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90 | |
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91 | C_Rint(1) = 1.24*rad |
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92 | C_Rext(1) = 1.29*rad |
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93 | C_Rint(2) = 1.29*rad |
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94 | C_Rext(2) = 1.43*rad |
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95 | C_Rint(3) = 1.43*rad |
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96 | C_Rext(3) = 1.53*rad |
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97 | |
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98 | Ca_Rint(1) = 1.95*rad |
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99 | Ca_Rext(1) = 1.99*rad |
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100 | Ca_Rint(2) = 1.99*rad |
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101 | Ca_Rext(2) = 2.03*rad |
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102 | |
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103 | |
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104 | ! Opacities of the rings |
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105 | tau_A(1) = 1.24 |
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106 | tau_A(2) = 0.81 |
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107 | tau_A(3) = 0.67 |
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108 | tau_A(4) = 0.58 |
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109 | |
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110 | tau_B(1) = 1.29 |
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111 | tau_B(2) = 5.13 |
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112 | tau_B(3) = 2.84 |
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113 | |
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114 | tau_C(1) = 0.06 |
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115 | tau_C(2) = 0.10 |
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116 | tau_C(3) = 0.14 |
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117 | |
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118 | tau_Ca(1) = 0.06 |
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119 | tau_Ca(2) = 0.24 |
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120 | |
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121 | ! Convert to cartesian coordinates |
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122 | N(:) = rad / sqrt(1-(e**2)*sinlat(:)**2) |
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123 | x(:) = N(:)*coslat(:)*coslon(:) |
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124 | y(:) = N(:)*coslat(:)*sinlon(:) |
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125 | z(:) = N(:)*(1-e**2)*sinlat(:) |
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126 | |
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127 | ! 2) LOCATION OF THE SUBSOLAR POINT |
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128 | |
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129 | ! subsolar longitude is deduced from time fraction ptime |
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130 | ! SG: the minus sign is important! ... otherwise subsolar point adopts a reverse rotation |
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131 | phi_S = -(ptime - 0.5)*2.*pi |
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132 | ! write(*,*) 'subsol point coords : ', declin*180./pi, phi_S*180./pi |
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133 | |
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134 | ! subsolar latitude is declin (declination of the sun) |
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135 | ! now convert in cartesian coordinates : |
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136 | Ns = rad/sqrt(1-(e**2)*sin(declin)**2) |
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137 | xs = Ns*cos(declin)*cos(phi_S) |
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138 | ys = Ns*cos(declin)*sin(phi_S) |
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139 | zs = Ns*(1-e**2)*sin(declin) |
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140 | |
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141 | ! 3) WHERE DOES THE INCIDENT RAY OF SUN CROSS THE EQUATORIAL PLAN ? |
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142 | |
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143 | k(:) = -z(:)/zs |
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144 | r(:) = (k(:)*xs + x(:))**2 + (k(:)*ys + y(:))**2 |
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145 | r(:) = sqrt(r(:)) |
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146 | |
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147 | ! 4) SO WHERE ARE THE SHADOW OF THESE RINGS ? |
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148 | |
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149 | ! Summer hemisphere is not under the shadow of the rings |
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150 | where(latitude(:)*declin .gt. 0.) |
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151 | eclipse(:) = 1000. |
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152 | end where |
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153 | |
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154 | ! No shadow of the rings by night |
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155 | where(x(:)*xs + y(:)*ys + z(:)*zs .lt. 0.) |
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156 | eclipse(:) = 1000. |
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157 | end where |
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158 | |
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159 | ! if the incident rays of sun cross a ring, there is a shadow |
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160 | do i=1, nb_A |
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161 | where(r(:) .ge. A_Rint(i) .and. r(:) .le. A_Rext(i) .and. eclipse(:) .ne. 1000.) |
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162 | eclipse(:) = 1. - exp(-tau_A(i)/abs(sin(declin))) |
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163 | end where |
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164 | end do |
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165 | |
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166 | do i=1, nb_B |
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167 | where(r(:) .ge. B_Rint(i) .and. r(:) .le. B_Rext(i) .and. eclipse(:) .ne. 1000.) |
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168 | eclipse(:) = 1. - exp(-tau_B(i)/abs(sin(declin))) |
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169 | end where |
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170 | enddo |
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171 | |
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172 | do i=1, nb_C |
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173 | where(r(:) .ge. C_Rint(i) .and. r(:) .le. C_Rext(i) .and. eclipse(:) .ne. 1000.) |
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174 | eclipse(:) = 1. - exp(-tau_C(i)/abs(sin(declin))) |
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175 | end where |
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176 | enddo |
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177 | |
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178 | do i=1, nb_ca |
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179 | where(r(:) .ge. Ca_Rint(i) .and. r(:) .le. Ca_Rext(i) .and. eclipse(:) .ne. 1000.) |
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180 | eclipse(:) = 1. - exp(-tau_Ca(i)/abs(sin(declin))) |
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181 | end where |
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182 | enddo |
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183 | |
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184 | ! At the other places and the excluded ones, eclipse is 0. |
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185 | where(eclipse(:) .eq. 2000. .or. eclipse(:) .eq. 1000.) |
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186 | eclipse(:) = 0. |
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187 | end where |
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188 | |
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189 | ! 5) CLEAN THE PLACE |
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190 | DEALLOCATE(x) |
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191 | DEALLOCATE(y) |
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192 | DEALLOCATE(z) |
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193 | DEALLOCATE(k) |
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194 | DEALLOCATE(N) |
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195 | DEALLOCATE(r) |
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196 | |
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197 | END SUBROUTINE rings |
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