1 | |
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2 | ! $Id$ |
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3 | |
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4 | MODULE grid_noro_m |
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5 | |
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6 | !******************************************************************************* |
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7 | |
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8 | USE lmdz_print_control, ONLY: lunout |
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9 | USE lmdz_assert_eq, ONLY: assert_eq |
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10 | PRIVATE |
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11 | PUBLIC :: grid_noro, grid_noro0, read_noro |
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12 | |
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13 | |
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14 | CONTAINS |
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15 | |
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16 | |
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17 | !------------------------------------------------------------------------------- |
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18 | |
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19 | SUBROUTINE grid_noro(xd,yd,zd,x,y,zphi,zmea,zstd,zsig,zgam,zthe,zpic,zval,mask) |
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20 | |
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21 | !------------------------------------------------------------------------------- |
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22 | ! Author: F. Lott (see also Z.X. Li, A. Harzallah et L. Fairhead) |
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23 | !------------------------------------------------------------------------------- |
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24 | ! Purpose: Compute the Parameters of the SSO scheme as described in LOTT &MILLER |
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25 | ! (1997) and LOTT(1999). |
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26 | !------------------------------------------------------------------------------- |
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27 | ! Comments: |
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28 | ! * Target points are on a rectangular grid: |
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29 | ! iim+1 latitudes including North and South Poles; |
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30 | ! jjm+1 longitudes, with periodicity jjm+1=1. |
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31 | ! * At the poles, the fields value is repeated jjm+1 time. |
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32 | ! * The parameters a,b,c,d represent the limits of the target gridpoint region. |
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33 | ! The means over this region are calculated from USN data, ponderated by a |
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34 | ! weight proportional to the surface occupated by the data inside the model |
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35 | ! gridpoint area. In most circumstances, this weight is the ratio between the |
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36 | ! surfaces of the USN gridpoint area and the model gridpoint area. |
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37 | |
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38 | ! (c) |
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39 | ! ----d----- |
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40 | ! | . . . .| |
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41 | ! | | |
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42 | ! (b)a . * . .b(a) |
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43 | ! | | |
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44 | ! | . . . .| |
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45 | ! ----c----- |
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46 | ! (d) |
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47 | ! * Hard-coded US Navy dataset dimensions (imdp=2160 ; jmdp=1080) have been |
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48 | ! removed (ALLOCATABLE used). |
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49 | ! * iext (currently 10% of imdp) represents the margin to ensure output cells |
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50 | ! on the edge are contained in input cells. |
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51 | !=============================================================================== |
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52 | IMPLICIT NONE |
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53 | !------------------------------------------------------------------------------- |
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54 | ! Arguments: |
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55 | REAL, INTENT(IN) :: xd(:), yd(:) !--- INPUT COORDINATES (imdp) (jmdp) |
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56 | REAL, INTENT(IN) :: zd(:,:) !--- INPUT FIELD (imdp,jmdp) |
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57 | REAL, INTENT(IN) :: x(:), y(:) !--- OUTPUT COORDINATES (imar+1) (jmar) |
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58 | REAL, INTENT(OUT) :: zphi(:,:) !--- GEOPOTENTIAL (imar+1,jmar) |
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59 | REAL, INTENT(OUT) :: zmea(:,:) !--- MEAN OROGRAPHY (imar+1,jmar) |
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60 | REAL, INTENT(OUT) :: zstd(:,:) !--- STANDARD DEVIATION (imar+1,jmar) |
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61 | REAL, INTENT(OUT) :: zsig(:,:) !--- SLOPE (imar+1,jmar) |
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62 | REAL, INTENT(OUT) :: zgam(:,:) !--- ANISOTROPY (imar+1,jmar) |
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63 | REAL, INTENT(OUT) :: zthe(:,:) !--- SMALL AXIS ORIENTATION (imar+1,jmar) |
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64 | REAL, INTENT(OUT) :: zpic(:,:) !--- MAXIMUM ALTITITUDE (imar+1,jmar) |
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65 | REAL, INTENT(OUT) :: zval(:,:) !--- MINIMUM ALTITITUDE (imar+1,jmar) |
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66 | REAL, INTENT(OUT) :: mask(:,:) !--- MASK (imar+1,jmar) |
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67 | !------------------------------------------------------------------------------- |
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68 | ! Local variables: |
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69 | CHARACTER(LEN=256) :: modname="grid_noro" |
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70 | REAL, ALLOCATABLE :: xusn(:), yusn(:) ! dim (imdp+2*iext) (jmdp+2) |
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71 | REAL, ALLOCATABLE :: zusn(:,:) ! dim (imdp+2*iext,jmdp+2) |
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72 | ! CORRELATIONS OF OROGRAPHY GRADIENT ! dim (imar+1,jmar) |
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73 | REAL, ALLOCATABLE :: ztz(:,:), zxtzx(:,:), zytzy(:,:), zxtzy(:,:), weight(:,:) |
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74 | ! CORRELATIONS OF USN OROGRAPHY GRADIENTS ! dim (imar+2*iext,jmdp+2) |
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75 | REAL, ALLOCATABLE :: zxtzxusn(:,:), zytzyusn(:,:), zxtzyusn(:,:) |
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76 | REAL, ALLOCATABLE :: num_tot(:,:), num_lan(:,:) ! dim (imar+1,jmar) |
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77 | REAL, ALLOCATABLE :: a(:), b(:) ! dim (imar+1) |
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78 | REAL, ALLOCATABLE :: c(:), d(:) ! dim (jmar) |
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79 | LOGICAL :: masque_lu |
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80 | INTEGER :: i, ii, imdp, imar, iext |
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81 | INTEGER :: j, jj, jmdp, jmar, nn |
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82 | REAL :: xpi, zdeltax, zlenx, weighx, xincr, zweinor, xk, xl, xm |
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83 | REAL :: rad, zdeltay, zleny, weighy, masque, zweisud, xp, xq, xw |
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84 | |
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85 | |
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86 | |
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87 | !------------------------------------------------------------------------------- |
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88 | imdp=assert_eq(SIZE(xd),SIZE(zd,1),TRIM(modname)//" imdp") |
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89 | jmdp=assert_eq(SIZE(yd),SIZE(zd,2),TRIM(modname)//" jmdp") |
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90 | imar=assert_eq([SIZE(x),SIZE(zphi,1),SIZE(zmea,1),SIZE(zstd,1),SIZE(zsig,1), & |
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91 | SIZE(zgam,1),SIZE(zthe,1),SIZE(zpic,1),SIZE(zval,1), & |
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92 | SIZE(mask,1)],TRIM(modname)//" imar")-1 |
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93 | jmar=assert_eq([SIZE(y),SIZE(zphi,2),SIZE(zmea,2),SIZE(zstd,2),SIZE(zsig,2), & |
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94 | SIZE(zgam,2),SIZE(zthe,2),SIZE(zpic,2),SIZE(zval,2), & |
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95 | SIZE(mask,2)],TRIM(modname)//" jmar") |
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96 | ! IF(imar/=iim) CALL abort_physic(TRIM(modname),'imar/=iim' ,1) |
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97 | ! IF(jmar/=jjm+1) CALL abort_physic(TRIM(modname),'jmar/=jjm+1',1) |
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98 | iext=imdp/10 !--- OK up to 36 degrees cell |
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99 | xpi = ACOS(-1.) |
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100 | rad = 6371229. |
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101 | zdeltay=2.*xpi/REAL(jmdp)*rad |
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102 | WRITE(lunout,*)"*** Orography parameters at sub-cell scale ***" |
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103 | |
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104 | !--- ARE WE USING A READ MASK ? |
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105 | masque_lu=ANY(mask/=-99999.); IF(.NOT.masque_lu) mask=0.0 |
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106 | WRITE(lunout,*)'Masque lu: ',masque_lu |
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107 | |
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108 | !--- EXTENSION OF THE INPUT DATABASE TO PROCEED COMPUTATIONS AT BOUNDARIES: |
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109 | ALLOCATE(xusn(imdp+2*iext)) |
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110 | xusn(1 +iext:imdp +iext)=xd(:) |
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111 | xusn(1 : iext)=xd(1+imdp-iext:imdp)-2.*xpi |
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112 | xusn(1+imdp+iext:imdp+2*iext)=xd(1 :iext)+2.*xpi |
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113 | |
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114 | ALLOCATE(yusn(jmdp+2)) |
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115 | yusn(1 )=yd(1) +(yd(1) -yd(2)) |
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116 | yusn(2:jmdp+1)=yd(:) |
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117 | yusn( jmdp+2)=yd(jmdp)+(yd(jmdp)-yd(jmdp-1)) |
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118 | |
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119 | ALLOCATE(zusn(imdp+2*iext,jmdp+2)) |
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120 | zusn(1 +iext:imdp +iext,2:jmdp+1)=zd (: , :) |
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121 | zusn(1 : iext,2:jmdp+1)=zd (imdp-iext+1:imdp , :) |
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122 | zusn(1+imdp +iext:imdp+2*iext,2:jmdp+1)=zd (1:iext , :) |
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123 | zusn(1 :imdp/2+iext, 1)=zusn(1+imdp/2:imdp +iext, 2) |
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124 | zusn(1+imdp/2+iext:imdp+2*iext, 1)=zusn(1 :imdp/2+iext, 2) |
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125 | zusn(1 :imdp/2+iext, jmdp+2)=zusn(1+imdp/2:imdp +iext,jmdp+1) |
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126 | zusn(1+imdp/2+iext:imdp+2*iext, jmdp+2)=zusn(1 :imdp/2+iext,jmdp+1) |
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127 | |
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128 | !--- COMPUTE LIMITS OF MODEL GRIDPOINT AREA (REGULAR GRID) |
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129 | ALLOCATE(a(imar+1),b(imar+1)) |
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130 | b(1:imar)=(x(1:imar )+ x(2:imar+1))/2.0 |
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131 | b(imar+1)= x( imar+1)+(x( imar+1)-x(imar))/2.0 |
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132 | a(1)=x(1)-(x(2)-x(1))/2.0 |
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133 | a(2:imar+1)= b(1:imar) |
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134 | |
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135 | ALLOCATE(c(jmar),d(jmar)) |
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136 | d(1:jmar-1)=(y(1:jmar-1)+ y(2:jmar))/2.0 |
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137 | d( jmar )= y( jmar )+(y( jmar)-y(jmar-1))/2.0 |
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138 | c(1)=y(1)-(y(2)-y(1))/2.0 |
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139 | c(2:jmar)=d(1:jmar-1) |
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140 | |
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141 | !--- INITIALIZATIONS: |
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142 | ALLOCATE(weight(imar+1,jmar)); weight(:,:)= 0.0 |
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143 | ALLOCATE(zxtzx (imar+1,jmar)); zxtzx (:,:)= 0.0 |
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144 | ALLOCATE(zytzy (imar+1,jmar)); zytzy (:,:)= 0.0 |
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145 | ALLOCATE(zxtzy (imar+1,jmar)); zxtzy (:,:)= 0.0 |
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146 | ALLOCATE(ztz (imar+1,jmar)); ztz (:,:)= 0.0 |
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147 | zmea(:,:)= 0.0 |
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148 | zpic(:,:)=-1.E+10 |
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149 | zval(:,:)= 1.E+10 |
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150 | |
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151 | !--- COMPUTE SLOPES CORRELATIONS ON USN GRID |
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152 | ! CORRELATIONS OF USN OROGRAPHY GRADIENTS ! dim (imdp+2*iext,jmdp+2) |
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153 | ALLOCATE(zytzyusn(imdp+2*iext,jmdp+2)); zytzyusn(:,:)=0.0 |
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154 | ALLOCATE(zxtzxusn(imdp+2*iext,jmdp+2)); zxtzxusn(:,:)=0.0 |
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155 | ALLOCATE(zxtzyusn(imdp+2*iext,jmdp+2)); zxtzyusn(:,:)=0.0 |
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156 | DO j = 2, jmdp+1 |
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157 | zdeltax=zdeltay*cos(yusn(j)) |
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158 | DO i = 2, imdp+2*iext-1 |
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159 | zytzyusn(i,j)=(zusn(i,j+1)-zusn(i,j-1))**2/zdeltay**2 |
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160 | zxtzxusn(i,j)=(zusn(i+1,j)-zusn(i-1,j))**2/zdeltax**2 |
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161 | zxtzyusn(i,j)=(zusn(i,j+1)-zusn(i,j-1)) /zdeltay & |
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162 | *(zusn(i+1,j)-zusn(i-1,j)) /zdeltax |
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163 | END DO |
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164 | END DO |
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165 | |
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166 | !--- SUMMATION OVER GRIDPOINT AREA |
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167 | zleny=xpi/REAL(jmdp)*rad |
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168 | xincr=xpi/REAL(jmdp)/2. |
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169 | ALLOCATE(num_tot(imar+1,jmar)); num_tot(:,:)=0. |
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170 | ALLOCATE(num_lan(imar+1,jmar)); num_lan(:,:)=0. |
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171 | DO ii = 1, imar+1 |
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172 | DO jj = 1, jmar |
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173 | DO j = 2,jmdp+1 |
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174 | zlenx=zleny*COS(yusn(j)) |
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175 | zdeltax=zdeltay*COS(yusn(j)) |
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176 | weighy=(xincr+AMIN1(c(jj)-yusn(j),yusn(j)-d(jj)))*rad |
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177 | weighy=AMAX1(0.,AMIN1(weighy,zleny)) |
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178 | |
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179 | IF(weighy==0.) CYCLE |
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180 | DO i = 2, imdp+2*iext-1 |
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181 | weighx=(xincr+AMIN1(xusn(i)-a(ii),b(ii)-xusn(i)))*rad*COS(yusn(j)) |
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182 | weighx=AMAX1(0.,AMIN1(weighx,zlenx)) |
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183 | |
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184 | IF(weighx==0.) CYCLE |
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185 | num_tot(ii,jj)=num_tot(ii,jj)+1.0 |
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186 | IF(zusn(i,j)>=1.)num_lan(ii,jj)=num_lan(ii,jj)+1.0 |
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187 | weight(ii,jj)=weight(ii,jj)+weighx*weighy |
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188 | zxtzx(ii,jj)=zxtzx(ii,jj)+zxtzxusn(i,j)*weighx*weighy |
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189 | zytzy(ii,jj)=zytzy(ii,jj)+zytzyusn(i,j)*weighx*weighy |
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190 | zxtzy(ii,jj)=zxtzy(ii,jj)+zxtzyusn(i,j)*weighx*weighy |
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191 | ztz (ii,jj)= ztz(ii,jj)+zusn(i,j)*zusn(i,j)*weighx*weighy |
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192 | zmea (ii,jj)= zmea(ii,jj)+zusn(i,j)*weighx*weighy !--- MEAN |
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193 | zpic (ii,jj)=AMAX1(zpic(ii,jj),zusn(i,j)) !--- PEAKS |
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194 | zval (ii,jj)=AMIN1(zval(ii,jj),zusn(i,j)) !--- VALLEYS |
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195 | END DO |
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196 | END DO |
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197 | END DO |
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198 | END DO |
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199 | |
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200 | !--- COMPUTE PARAMETERS NEEDED BY LOTT & MILLER (1997) AND LOTT (1999) SSO SCHEME |
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201 | IF(.NOT.masque_lu) THEN |
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202 | WHERE(weight(:,:)/=0.0) mask=num_lan(:,:)/num_tot(:,:) |
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203 | END IF |
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204 | nn=COUNT(weight(:,:)==0.0) |
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205 | IF(nn/=0) WRITE(lunout,*)'Problem with weight ; vanishing occurrences: ',nn |
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206 | WHERE(weight(:,:)/=0.0) |
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207 | zmea (:,:)=zmea (:,:)/weight(:,:) |
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208 | zxtzx(:,:)=zxtzx(:,:)/weight(:,:) |
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209 | zytzy(:,:)=zytzy(:,:)/weight(:,:) |
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210 | zxtzy(:,:)=zxtzy(:,:)/weight(:,:) |
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211 | ztz (:,:)=ztz (:,:)/weight(:,:) |
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212 | zstd (:,:)=ztz (:,:)-zmea(:,:)**2 |
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213 | END WHERE |
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214 | WHERE(zstd(:,:)<0) zstd(:,:)=0. |
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215 | zstd (:,:)=SQRT(zstd(:,:)) |
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216 | |
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217 | !--- CORRECT VALUES OF HORIZONTAL SLOPE NEAR THE POLES: |
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218 | zxtzx(:, 1)=zxtzx(:, 2) |
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219 | zxtzx(:,jmar)=zxtzx(:,jmar-1) |
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220 | zxtzy(:, 1)=zxtzy(:, 2) |
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221 | zxtzy(:,jmar)=zxtzy(:,jmar-1) |
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222 | zytzy(:, 1)=zytzy(:, 2) |
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223 | zytzy(:,jmar)=zytzy(:,jmar-1) |
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224 | |
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225 | !=== FILTERS TO SMOOTH OUT FIELDS FOR INPUT INTO SSO SCHEME. |
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226 | !--- FIRST FILTER, MOVING AVERAGE OVER 9 POINTS. |
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227 | !------------------------------------------------------------------------------- |
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228 | zphi(:,:)=zmea(:,:) ! GK211005 (CG) UNSMOOTHED TOPO |
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229 | |
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230 | CALL MVA9(zmea); CALL MVA9(zstd); CALL MVA9(zpic); CALL MVA9(zval) |
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231 | CALL MVA9(zxtzx); CALL MVA9(zxtzy); CALL MVA9(zytzy) |
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232 | |
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233 | !--- MASK BASED ON GROUND MAXIMUM, 10% THRESHOLD. (SURFACE PARAMS MEANINGLESS) |
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234 | WHERE(weight(:,:)==0.0.OR.mask<0.1) |
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235 | zphi(:,:)=0.0; zmea(:,:)=0.0; zpic(:,:)=0.0; zval(:,:)=0.0; zstd(:,:)=0.0 |
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236 | END WHERE |
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237 | DO ii = 1, imar |
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238 | DO jj = 1, jmar |
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239 | IF(weight(ii,jj)==0.0) CYCLE |
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240 | !--- Coefficients K, L et M: |
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241 | xk=(zxtzx(ii,jj)+zytzy(ii,jj))/2. |
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242 | xl=(zxtzx(ii,jj)-zytzy(ii,jj))/2. |
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243 | xm=zxtzy(ii,jj) |
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244 | xp=xk-SQRT(xl**2+xm**2) |
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245 | xq=xk+SQRT(xl**2+xm**2) |
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246 | xw=1.e-8 |
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247 | IF(xp<=xw) xp=0. |
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248 | IF(xq<=xw) xq=xw |
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249 | IF(ABS(xm)<=xw) xm=xw*SIGN(1.,xm) |
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250 | !--- SLOPE, ANISOTROPY AND THETA ANGLE |
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251 | zsig(ii,jj)=SQRT(xq) |
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252 | zgam(ii,jj)=xp/xq |
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253 | zthe(ii,jj)=90.*ATAN2(xm,xl)/xpi |
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254 | END DO |
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255 | END DO |
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256 | WHERE(weight(:,:)==0.0.OR.mask<0.1) |
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257 | zsig(:,:)=0.0; zgam(:,:)=0.0; zthe(:,:)=0.0 |
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258 | END WHERE |
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259 | |
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260 | WRITE(lunout,*)' MEAN ORO:' ,MAXVAL(zmea) |
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261 | WRITE(lunout,*)' ST. DEV.:' ,MAXVAL(zstd) |
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262 | WRITE(lunout,*)' PENTE:' ,MAXVAL(zsig) |
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263 | WRITE(lunout,*)' ANISOTROP:',MAXVAL(zgam) |
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264 | WRITE(lunout,*)' ANGLE:' ,MINVAL(zthe),MAXVAL(zthe) |
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265 | WRITE(lunout,*)' pic:' ,MAXVAL(zpic) |
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266 | WRITE(lunout,*)' val:' ,MAXVAL(zval) |
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267 | |
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268 | !--- Values at redundant longitude |
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269 | zmea(imar+1,:)=zmea(1,:) |
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270 | zphi(imar+1,:)=zphi(1,:) |
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271 | zpic(imar+1,:)=zpic(1,:) |
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272 | zval(imar+1,:)=zval(1,:) |
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273 | zstd(imar+1,:)=zstd(1,:) |
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274 | zsig(imar+1,:)=zsig(1,:) |
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275 | zgam(imar+1,:)=zgam(1,:) |
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276 | zthe(imar+1,:)=zthe(1,:) |
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277 | |
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278 | !--- Values at north pole |
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279 | zweinor =SUM(weight(1:imar,1)) |
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280 | zmea(:,1)=SUM(weight(1:imar,1)*zmea(1:imar,1))/zweinor |
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281 | zphi(:,1)=SUM(weight(1:imar,1)*zphi(1:imar,1))/zweinor |
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282 | zpic(:,1)=SUM(weight(1:imar,1)*zpic(1:imar,1))/zweinor |
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283 | zval(:,1)=SUM(weight(1:imar,1)*zval(1:imar,1))/zweinor |
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284 | zstd(:,1)=SUM(weight(1:imar,1)*zstd(1:imar,1))/zweinor |
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285 | zsig(:,1)=SUM(weight(1:imar,1)*zsig(1:imar,1))/zweinor |
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286 | zgam(:,1)=1.; zthe(:,1)=0. |
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287 | |
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288 | !--- Values at south pole |
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289 | zweisud =SUM(weight(1:imar,jmar),DIM=1) |
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290 | zmea(:,jmar)=SUM(weight(1:imar,jmar)*zmea(1:imar,jmar))/zweisud |
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291 | zphi(:,jmar)=SUM(weight(1:imar,jmar)*zphi(1:imar,jmar))/zweisud |
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292 | zpic(:,jmar)=SUM(weight(1:imar,jmar)*zpic(1:imar,jmar))/zweisud |
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293 | zval(:,jmar)=SUM(weight(1:imar,jmar)*zval(1:imar,jmar))/zweisud |
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294 | zstd(:,jmar)=SUM(weight(1:imar,jmar)*zstd(1:imar,jmar))/zweisud |
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295 | zsig(:,jmar)=SUM(weight(1:imar,jmar)*zsig(1:imar,jmar))/zweisud |
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296 | zgam(:,jmar)=1.; zthe(:,jmar)=0. |
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297 | |
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298 | END SUBROUTINE grid_noro |
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299 | |
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300 | !------------------------------------------------------------------------------- |
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301 | |
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302 | |
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303 | !------------------------------------------------------------------------------- |
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304 | |
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305 | SUBROUTINE grid_noro0(xd,yd,zd,x,y,zphi,mask) |
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306 | |
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307 | !=============================================================================== |
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308 | ! Purpose: Extracted from grid_noro to provide geopotential height for dynamics |
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309 | ! without any CALL to physics subroutines. |
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310 | !=============================================================================== |
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311 | IMPLICIT NONE |
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312 | !------------------------------------------------------------------------------- |
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313 | ! Arguments: |
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314 | REAL, INTENT(IN) :: xd(:), yd(:) !--- INPUT COORDINATES (imdp) (jmdp) |
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315 | REAL, INTENT(IN) :: zd(:,:) !--- INPUT FIELD (imdp, jmdp) |
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316 | REAL, INTENT(IN) :: x(:), y(:) !--- OUTPUT COORDINATES (imar+1) (jmar) |
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317 | REAL, INTENT(OUT) :: zphi(:,:) !--- GEOPOTENTIAL (imar+1,jmar) |
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318 | REAL, INTENT(OUT) :: mask(:,:) !--- MASK (imar+1,jmar) |
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319 | !------------------------------------------------------------------------------- |
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320 | ! Local variables: |
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321 | CHARACTER(LEN=256) :: modname="grid_noro0" |
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322 | REAL, ALLOCATABLE :: xusn(:), yusn(:) ! dim (imdp+2*iext) (jmdp+2) |
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323 | REAL, ALLOCATABLE :: zusn(:,:) ! dim (imdp+2*iext, jmdp+2) |
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324 | REAL, ALLOCATABLE :: weight(:,:) ! dim (imar+1,jmar) |
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325 | REAL, ALLOCATABLE :: num_tot(:,:), num_lan(:,:) ! dim (imar+1,jmar) |
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326 | REAL, ALLOCATABLE :: a(:), b(:) ! dim (imar+1) |
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327 | REAL, ALLOCATABLE :: c(:), d(:) ! dim (jmar) |
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328 | |
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329 | LOGICAL :: masque_lu |
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330 | INTEGER :: i, ii, imdp, imar, iext |
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331 | INTEGER :: j, jj, jmdp, jmar, nn |
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332 | REAL :: xpi, zlenx, zleny, weighx, weighy, xincr, masque, rad |
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333 | |
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334 | !------------------------------------------------------------------------------- |
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335 | imdp=assert_eq(SIZE(xd),SIZE(zd,1),TRIM(modname)//" imdp") |
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336 | jmdp=assert_eq(SIZE(yd),SIZE(zd,2),TRIM(modname)//" jmdp") |
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337 | imar=assert_eq(SIZE(x),SIZE(zphi,1),SIZE(mask,1),TRIM(modname)//" imar")-1 |
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338 | jmar=assert_eq(SIZE(y),SIZE(zphi,2),SIZE(mask,2),TRIM(modname)//" jmar") |
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339 | iext=imdp/10 |
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340 | xpi = ACOS(-1.) |
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341 | rad = 6371229. |
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342 | |
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343 | !--- ARE WE USING A READ MASK ? |
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344 | masque_lu=ANY(mask/=-99999.); IF(.NOT.masque_lu) mask=0.0 |
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345 | WRITE(lunout,*)'Masque lu: ',masque_lu |
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346 | |
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347 | !--- EXTENSION OF THE INPUT DATABASE TO PROCEED COMPUTATIONS AT BOUNDARIES: |
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348 | ALLOCATE(xusn(imdp+2*iext)) |
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349 | xusn(1 +iext:imdp +iext)=xd(:) |
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350 | xusn(1 : iext)=xd(1+imdp-iext:imdp)-2.*xpi |
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351 | xusn(1+imdp+iext:imdp+2*iext)=xd(1 :iext)+2.*xpi |
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352 | |
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353 | ALLOCATE(yusn(jmdp+2)) |
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354 | yusn(1 )=yd(1) +(yd(1) -yd(2)) |
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355 | yusn(2:jmdp+1)=yd(:) |
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356 | yusn( jmdp+2)=yd(jmdp)+(yd(jmdp)-yd(jmdp-1)) |
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357 | |
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358 | ALLOCATE(zusn(imdp+2*iext,jmdp+2)) |
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359 | zusn(1 +iext:imdp +iext,2:jmdp+1)=zd (: , :) |
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360 | zusn(1 : iext,2:jmdp+1)=zd (imdp-iext+1:imdp , :) |
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361 | zusn(1+imdp +iext:imdp+2*iext,2:jmdp+1)=zd (1:iext , :) |
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362 | zusn(1 :imdp/2+iext, 1)=zusn(1+imdp/2:imdp +iext, 2) |
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363 | zusn(1+imdp/2+iext:imdp+2*iext, 1)=zusn(1 :imdp/2+iext, 2) |
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364 | zusn(1 :imdp/2+iext, jmdp+2)=zusn(1+imdp/2:imdp +iext,jmdp+1) |
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365 | zusn(1+imdp/2+iext:imdp+2*iext, jmdp+2)=zusn(1 :imdp/2+iext,jmdp+1) |
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366 | |
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367 | !--- COMPUTE LIMITS OF MODEL GRIDPOINT AREA (REGULAR GRID) |
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368 | ALLOCATE(a(imar+1),b(imar+1)) |
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369 | b(1:imar)=(x(1:imar )+ x(2:imar+1))/2.0 |
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370 | b(imar+1)= x( imar+1)+(x( imar+1)-x(imar))/2.0 |
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371 | a(1)=x(1)-(x(2)-x(1))/2.0 |
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372 | a(2:imar+1)= b(1:imar) |
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373 | |
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374 | ALLOCATE(c(jmar),d(jmar)) |
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375 | d(1:jmar-1)=(y(1:jmar-1)+ y(2:jmar))/2.0 |
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376 | d( jmar )= y( jmar )+(y( jmar)-y(jmar-1))/2.0 |
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377 | c(1)=y(1)-(y(2)-y(1))/2.0 |
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378 | c(2:jmar)=d(1:jmar-1) |
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379 | |
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380 | !--- INITIALIZATIONS: |
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381 | ALLOCATE(weight(imar+1,jmar)); weight(:,:)=0.0; zphi(:,:)=0.0 |
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382 | |
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383 | !--- SUMMATION OVER GRIDPOINT AREA |
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384 | zleny=xpi/REAL(jmdp)*rad |
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385 | xincr=xpi/REAL(jmdp)/2. |
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386 | ALLOCATE(num_tot(imar+1,jmar)); num_tot(:,:)=0. |
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387 | ALLOCATE(num_lan(imar+1,jmar)); num_lan(:,:)=0. |
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388 | DO ii = 1, imar+1 |
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389 | DO jj = 1, jmar |
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390 | DO j = 2,jmdp+1 |
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391 | zlenx=zleny*COS(yusn(j)) |
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392 | weighy=(xincr+AMIN1(c(jj)-yusn(j),yusn(j)-d(jj)))*rad |
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393 | weighy=AMAX1(0.,AMIN1(weighy,zleny)) |
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394 | IF(weighy/=0) CYCLE |
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395 | DO i = 2, imdp+2*iext-1 |
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396 | weighx=(xincr+AMIN1(xusn(i)-a(ii),b(ii)-xusn(i)))*rad*COS(yusn(j)) |
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397 | weighx=AMAX1(0.,AMIN1(weighx,zlenx)) |
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398 | IF(weighx/=0) CYCLE |
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399 | num_tot(ii,jj)=num_tot(ii,jj)+1.0 |
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400 | IF(zusn(i,j)>=1.)num_lan(ii,jj)=num_lan(ii,jj)+1.0 |
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401 | weight(ii,jj)=weight(ii,jj)+weighx*weighy |
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402 | zphi (ii,jj)=zphi (ii,jj)+zusn(i,j)*weighx*weighy !--- MEAN |
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403 | END DO |
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404 | END DO |
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405 | END DO |
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406 | END DO |
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407 | |
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408 | !--- COMPUTE PARAMETERS NEEDED BY LOTT & MILLER (1997) AND LOTT (1999) SSO SCHEME |
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409 | IF(.NOT.masque_lu) THEN |
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410 | WHERE(weight(:,:)/=0.0) mask=num_lan(:,:)/num_tot(:,:) |
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411 | END IF |
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412 | nn=COUNT(weight(:,:)==0.0) |
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413 | IF(nn/=0) WRITE(lunout,*)'Problem with weight ; vanishing occurrences: ',nn |
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414 | WHERE(weight/=0.0) zphi(:,:)=zphi(:,:)/weight(:,:) |
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415 | |
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416 | !--- MASK BASED ON GROUND MAXIMUM, 10% THRESHOLD (<10%: SURF PARAMS MEANINGLESS) |
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417 | WHERE(weight(:,:)==0.0.OR.mask<0.1) zphi(:,:)=0.0 |
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418 | WRITE(lunout,*)' MEAN ORO:' ,MAXVAL(zphi) |
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419 | |
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420 | !--- Values at redundant longitude and at poles |
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421 | zphi(imar+1,:)=zphi(1,:) |
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422 | zphi(:, 1)=SUM(weight(1:imar, 1)*zphi(1:imar, 1))/SUM(weight(1:imar, 1)) |
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423 | zphi(:,jmar)=SUM(weight(1:imar,jmar)*zphi(1:imar,jmar))/SUM(weight(1:imar,jmar)) |
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424 | |
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425 | END SUBROUTINE grid_noro0 |
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426 | |
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427 | !------------------------------------------------------------------------------- |
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428 | |
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429 | |
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430 | !------------------------------------------------------------------------------- |
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431 | |
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432 | SUBROUTINE read_noro(x,y,fname,zphi,zmea,zstd,zsig,zgam,zthe,zpic,zval,mask) |
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433 | |
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434 | !------------------------------------------------------------------------------- |
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435 | ! Purpose: Read parameters usually determined with grid_noro from a file. |
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436 | !=============================================================================== |
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437 | USE netcdf, ONLY: nf90_open, nf90_inq_dimid, nf90_inquire_dimension, & |
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438 | nf90_noerr, nf90_close, nf90_inq_varid, nf90_get_var, nf90_strerror, & |
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439 | nf90_nowrite |
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440 | IMPLICIT NONE |
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441 | !------------------------------------------------------------------------------- |
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442 | ! Arguments: |
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443 | REAL, INTENT(IN) :: x(:), y(:) !--- OUTPUT COORDINATES (imar+1) (jmar) |
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444 | CHARACTER(LEN=*), INTENT(IN) :: fname ! PARAMETERS FILE NAME |
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445 | REAL, INTENT(OUT) :: zphi(:,:) !--- GEOPOTENTIAL (imar+1,jmar) |
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446 | REAL, INTENT(OUT) :: zmea(:,:) !--- MEAN OROGRAPHY (imar+1,jmar) |
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447 | REAL, INTENT(OUT) :: zstd(:,:) !--- STANDARD DEVIATION (imar+1,jmar) |
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448 | REAL, INTENT(OUT) :: zsig(:,:) !--- SLOPE (imar+1,jmar) |
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449 | REAL, INTENT(OUT) :: zgam(:,:) !--- ANISOTROPY (imar+1,jmar) |
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450 | REAL, INTENT(OUT) :: zthe(:,:) !--- SMALL AXIS ORIENTATION (imar+1,jmar) |
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451 | REAL, INTENT(OUT) :: zpic(:,:) !--- MAXIMUM ALTITUDE (imar+1,jmar) |
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452 | REAL, INTENT(OUT) :: zval(:,:) !--- MINIMUM ALTITUDE (imar+1,jmar) |
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453 | REAL, INTENT(OUT) :: mask(:,:) !--- MASK (imar+1,jmar) |
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454 | !------------------------------------------------------------------------------- |
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455 | ! Local variables: |
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456 | CHARACTER(LEN=256) :: modname="read_noro" |
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457 | INTEGER :: imar, jmar, fid, did, vid |
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458 | LOGICAL :: masque_lu |
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459 | REAL :: xpi, d2r |
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460 | !------------------------------------------------------------------------------- |
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461 | imar=assert_eq([SIZE(x),SIZE(zphi,1),SIZE(zmea,1),SIZE(zstd,1),SIZE(zsig,1), & |
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462 | SIZE(zgam,1),SIZE(zthe,1),SIZE(zpic,1),SIZE(zval,1), & |
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463 | SIZE(mask,1)],TRIM(modname)//" imar")-1 |
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464 | jmar=assert_eq([SIZE(y),SIZE(zphi,2),SIZE(zmea,2),SIZE(zstd,2),SIZE(zsig,2), & |
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465 | SIZE(zgam,2),SIZE(zthe,2),SIZE(zpic,2),SIZE(zval,2), & |
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466 | SIZE(mask,2)],TRIM(modname)//" jmar") |
---|
467 | xpi=ACOS(-1.0); d2r=xpi/180. |
---|
468 | WRITE(lunout,*)"*** Orography parameters at sub-cell scale from file ***" |
---|
469 | |
---|
470 | !--- ARE WE USING A READ MASK ? |
---|
471 | masque_lu=ANY(mask/=-99999.); IF(.NOT.masque_lu) mask=0.0 |
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472 | WRITE(lunout,*)'Masque lu: ',masque_lu |
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473 | CALL ncerr(nf90_open(fname,nf90_nowrite,fid)) |
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474 | CALL check_dim('x','longitude',x(1:imar)) |
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475 | CALL check_dim('y','latitude' ,y(1:jmar)) |
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476 | IF(.NOT.masque_lu) CALL get_fld('mask',mask) |
---|
477 | CALL get_fld('Zphi',zphi) |
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478 | CALL get_fld('Zmea',zmea) |
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479 | CALL get_fld('mu' ,zstd) |
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480 | CALL get_fld('Zsig',zsig) |
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481 | CALL get_fld('Zgam',zgam) |
---|
482 | CALL get_fld('Zthe',zthe) |
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483 | zpic=zmea+2*zstd |
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484 | zval=MAX(0.,zmea-2.*zstd) |
---|
485 | CALL ncerr(nf90_close(fid)) |
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486 | WRITE(lunout,*)' MEAN ORO:' ,MAXVAL(zmea) |
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487 | WRITE(lunout,*)' ST. DEV.:' ,MAXVAL(zstd) |
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488 | WRITE(lunout,*)' PENTE:' ,MAXVAL(zsig) |
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489 | WRITE(lunout,*)' ANISOTROP:',MAXVAL(zgam) |
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490 | WRITE(lunout,*)' ANGLE:' ,MINVAL(zthe),MAXVAL(zthe) |
---|
491 | WRITE(lunout,*)' pic:' ,MAXVAL(zpic) |
---|
492 | WRITE(lunout,*)' val:' ,MAXVAL(zval) |
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493 | |
---|
494 | CONTAINS |
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495 | |
---|
496 | |
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497 | SUBROUTINE get_fld(var,fld) |
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498 | CHARACTER(LEN=*), INTENT(IN) :: var |
---|
499 | REAL, INTENT(INOUT) :: fld(:,:) |
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500 | CALL ncerr(nf90_inq_varid(fid,var,vid),var) |
---|
501 | CALL ncerr(nf90_get_var(fid,vid,fld(1:imar,:)),var) |
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502 | fld(imar+1,:)=fld(1,:) |
---|
503 | END SUBROUTINE get_fld |
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504 | |
---|
505 | SUBROUTINE check_dim(dimd,nam,dimv) |
---|
506 | USE lmdz_abort_physic, ONLY: abort_physic |
---|
507 | CHARACTER(LEN=*), INTENT(IN) :: dimd |
---|
508 | CHARACTER(LEN=*), INTENT(IN) :: nam |
---|
509 | REAL, INTENT(IN) :: dimv(:) |
---|
510 | REAL, ALLOCATABLE :: tmp(:) |
---|
511 | INTEGER :: n |
---|
512 | CALL ncerr(nf90_inq_dimid(fid,dimd,did)) |
---|
513 | CALL ncerr(nf90_inquire_dimension(fid,did,len=n)); ALLOCATE(tmp(n)) |
---|
514 | CALL ncerr(nf90_inq_varid(fid,dimd,did)) |
---|
515 | CALL ncerr(nf90_get_var(fid,did,tmp)) |
---|
516 | IF(MAXVAL(tmp)>xpi) tmp=tmp*d2r |
---|
517 | IF(n/=SIZE(dimv).OR.ANY(ABS(tmp-dimv)>1E-6)) THEN |
---|
518 | WRITE(lunout,*)'Problem with file "'//TRIM(fname)//'".' |
---|
519 | CALL abort_physic(modname,'Grid differs from LMDZ for '//TRIM(nam)//'.',1) |
---|
520 | END IF |
---|
521 | END SUBROUTINE check_dim |
---|
522 | |
---|
523 | SUBROUTINE ncerr(ncres,var) |
---|
524 | USE lmdz_abort_physic, ONLY: abort_physic |
---|
525 | IMPLICIT NONE |
---|
526 | INTEGER, INTENT(IN) :: ncres |
---|
527 | CHARACTER(LEN=*), INTENT(IN), OPTIONAL :: var |
---|
528 | CHARACTER(LEN=256) :: mess |
---|
529 | IF(ncres/=nf90_noerr) THEN |
---|
530 | mess='Problem with file "'//TRIM(fname)//'"' |
---|
531 | IF(PRESENT(var)) mess=TRIM(mess)//' and variable "'//TRIM(var)//'"' |
---|
532 | WRITE(lunout,*)TRIM(mess)//'.' |
---|
533 | CALL abort_physic(modname,nf90_strerror(ncres),1) |
---|
534 | END IF |
---|
535 | END SUBROUTINE ncerr |
---|
536 | |
---|
537 | END SUBROUTINE read_noro |
---|
538 | |
---|
539 | !------------------------------------------------------------------------------- |
---|
540 | |
---|
541 | |
---|
542 | !------------------------------------------------------------------------------- |
---|
543 | |
---|
544 | SUBROUTINE MVA9(x) |
---|
545 | |
---|
546 | !------------------------------------------------------------------------------- |
---|
547 | IMPLICIT NONE |
---|
548 | ! MAKE A MOVING AVERAGE OVER 9 GRIDPOINTS OF THE X FIELDS |
---|
549 | !------------------------------------------------------------------------------- |
---|
550 | ! Arguments: |
---|
551 | REAL, INTENT(INOUT) :: x(:,:) |
---|
552 | !------------------------------------------------------------------------------- |
---|
553 | ! Local variables: |
---|
554 | REAL :: xf(SIZE(x,DIM=1),SIZE(x,DIM=2)), WEIGHTpb(-1:1,-1:1) |
---|
555 | INTEGER :: i, j, imar, jmar |
---|
556 | !------------------------------------------------------------------------------- |
---|
557 | WEIGHTpb=RESHAPE([((1./REAL((1+i**2)*(1+j**2)),i=-1,1),j=-1,1)],SHAPE=[3,3]) |
---|
558 | WEIGHTpb=WEIGHTpb/SUM(WEIGHTpb) |
---|
559 | imar=SIZE(X,DIM=1); jmar=SIZE(X,DIM=2) |
---|
560 | DO j=2,jmar-1 |
---|
561 | DO i=2,imar-1 |
---|
562 | xf(i,j)=SUM(x(i-1:i+1,j-1:j+1)*WEIGHTpb(:,:)) |
---|
563 | END DO |
---|
564 | END DO |
---|
565 | DO j=2,jmar-1 |
---|
566 | xf(1,j)=SUM(x(imar-1,j-1:j+1)*WEIGHTpb(-1,:)) |
---|
567 | xf(1,j)=xf(1,j)+SUM(x(1:2,j-1:j+1)*WEIGHTpb(0:1,-1:1)) |
---|
568 | xf(imar,j)=xf(1,j) |
---|
569 | END DO |
---|
570 | xf(:, 1)=xf(:, 2) |
---|
571 | xf(:,jmar)=xf(:,jmar-1) |
---|
572 | x(:,:)=xf(:,:) |
---|
573 | |
---|
574 | END SUBROUTINE MVA9 |
---|
575 | |
---|
576 | !------------------------------------------------------------------------------- |
---|
577 | |
---|
578 | |
---|
579 | END MODULE grid_noro_m |
---|
580 | |
---|
581 | |
---|