[2] | 1 | ;------------------------------------------------------------ |
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| 2 | ;------------------------------------------------------------ |
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| 3 | ;------------------------------------------------------------ |
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| 4 | ;+ |
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| 5 | ; |
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[142] | 6 | ; @file_comments |
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| 7 | ; averages a 2- or 3-d field over a selected |
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[2] | 8 | ; geographical area and along one ore more |
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| 9 | ; selected axes (x, y or z) |
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| 10 | ; |
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[142] | 11 | ; @categories |
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[2] | 12 | ; |
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[163] | 13 | ; @param TAB {in}{required} |
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[142] | 14 | ; 2 or 3d field |
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[2] | 15 | ; |
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[142] | 16 | ; @param DIREC {in}{required} |
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| 17 | ; 'x' 'y' 'z' 'xy' 'xz' 'yz' or 'xyz' |
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[2] | 18 | ; |
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[142] | 19 | ; @keyword BOXZOOM |
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| 20 | ; [xmin,xmax,ymin,ymax (,(zmin,)zmax)] to more details, see domdef |
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| 21 | ; boxzoom can have 5 forms: |
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[163] | 22 | ; [vert2], |
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| 23 | ; [vert1, vert2], |
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| 24 | ; [lon1, lon2, lat1, lat2], |
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| 25 | ; [lon1, lon2, lat1, lat2, vert2], |
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| 26 | ; [lon1, lon2, lat1, lat2, vert1,vert2] |
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[2] | 27 | ; |
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[142] | 28 | ; @keyword NAN |
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| 29 | ; not a number, we activate it if we want to average without considerate some masked values of TAB. |
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[163] | 30 | ; If masked values of TAB are values consecrated by IDL(!values.f_nan), we just have to put NAN. |
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[142] | 31 | ; If masked values of TAB are valued a (a must be different of 1, corresponding to nan = |
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| 32 | ; !values.f_nan and of 0, which desactivate nan). We have to put NAN=a. |
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[163] | 33 | ; Comment: In output, result points which are NAN will be valued a or !values.f_nan. |
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[142] | 34 | ; |
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| 35 | ; @keyword NODOMDEF |
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| 36 | ; We activate it if we do not want to pass in domdef even if the keyword boxzoom |
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| 37 | ; is present (like when grossemoyenne is called via checkfield) |
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[2] | 38 | ; |
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[142] | 39 | ; @keyword INTEGRATION |
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| 40 | ; To make an integral rather than an average |
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[25] | 41 | ; |
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[142] | 42 | ; @keyword WDEPTH |
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[163] | 43 | ; to specify that the field is at W depth instead of T |
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[142] | 44 | ; depth (automatically activated if vargrid eq 'W') |
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[2] | 45 | ; |
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[142] | 46 | ; @returns |
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| 47 | ; An array |
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[2] | 48 | ; |
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[142] | 49 | ; @uses |
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| 50 | ; common |
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| 51 | ; domdef |
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[2] | 52 | ; |
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[142] | 53 | ; @restrictions Put values corresponding to land at 1.e20 |
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[2] | 54 | ; |
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[142] | 55 | ; @history |
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[157] | 56 | ; Jerome Vialard (jv\@lodyc.jussieu.fr) |
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[2] | 57 | ; 2/7/98 |
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[157] | 58 | ; Sebastien Masson (smasson\@lodyc.jussieu.fr) |
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[2] | 59 | ; 14/8/98 |
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| 60 | ; 15/1/98 |
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[142] | 61 | ; 11/3/99 adaptation for NAN |
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| 62 | ; 28/7/99 Averages 1d arrays |
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| 63 | ; |
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| 64 | ; @version |
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| 65 | ; $Id$ |
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| 66 | ; |
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[2] | 67 | ;- |
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[142] | 68 | |
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[25] | 69 | function moyenne, tab, direc, BOXZOOM = boxzoom, INTEGRATION = integration $ |
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| 70 | , NAN = nan, NODOMDEF = nodomdef, WDEPTH = wdepth $ |
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| 71 | , _extra = ex |
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| 72 | ;--------------------------------------------------------- |
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[114] | 73 | ; |
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| 74 | compile_opt idl2, strictarrsubs |
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| 75 | ; |
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[25] | 76 | @cm_4mesh |
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| 77 | @cm_4data |
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| 78 | @cm_4cal |
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| 79 | IF NOT keyword_set(key_forgetold) THEN BEGIN |
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| 80 | @updatenew |
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| 81 | @updatekwd |
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| 82 | ENDIF |
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| 83 | ;--------------------------------------------------------- |
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[142] | 84 | tempsun = systime(1) ; To key_performance |
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[2] | 85 | ;------------------------------------------------------------ |
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[142] | 86 | ;I) preliminaries |
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[2] | 87 | ;------------------------------------------------------------ |
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[25] | 88 | dirt = 0 |
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| 89 | dirx = 0 |
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| 90 | diry = 0 |
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| 91 | dirz = 0 |
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[2] | 92 | ;------------------------------------------------------------ |
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[142] | 93 | ; I.1) Directions(s) we follow to integrate |
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[2] | 94 | ;------------------------------------------------------------ |
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[25] | 95 | if ( strpos(direc, 't') ge 0 ) then dirt = 1 |
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| 96 | if ( strpos(direc, 'x') ge 0 ) then dirx = 1 |
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| 97 | if ( strpos(direc, 'y') ge 0 ) then diry = 1 |
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| 98 | if ( strpos(direc, 'z') ge 0 ) then dirz = 1 |
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| 99 | if (dirx eq 0 and diry eq 0 and dirz eq 0) then return, tab |
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[2] | 100 | ;------------------------------------------------------------ |
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[142] | 101 | ; I.2) verification of the input array's size |
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[2] | 102 | ;------------------------------------------------------------ |
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[25] | 103 | taille = size(tab) |
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| 104 | case 1 of |
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| 105 | taille[0] eq 1 :dim = '1d' |
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| 106 | taille[0] eq 2 :BEGIN |
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| 107 | dim = '2d' |
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| 108 | if dirx eq 0 and diry eq 0 then return, tab |
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| 109 | END |
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| 110 | taille[0] eq 3 :BEGIN |
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| 111 | dim = '3d' |
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| 112 | if dirx eq 0 and diry eq 0 and dirz eq 0 then return, tab |
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| 113 | END |
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| 114 | else : return, report('Le tableau d''entree doit etre a 2 ou 3 dimensions s''il contient une dim temporelle utiliser grossemoyenne') |
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| 115 | endcase |
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[2] | 116 | ;------------------------------------------------------------ |
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[142] | 117 | ; I.3) Obtainment of scale's factors and of the mask on the subdomain concernedby the average. |
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| 118 | ; Redefinition of the domain ajusted at boxzoom (at 6 elements) |
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| 119 | ; This will allowed us to calculate only in the domain concerned by the average. |
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| 120 | ; Domdef, followed by grid give us all arrays of the grid on the subdomain |
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[2] | 121 | ;------------------------------------------------------------ |
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[25] | 122 | if keyword_set(boxzoom) then BEGIN |
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| 123 | Case 1 Of |
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| 124 | N_Elements(Boxzoom) Eq 1:bte = [lon1, lon2, lat1, lat2, 0., boxzoom[0]] |
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| 125 | N_Elements(Boxzoom) Eq 2:bte = [lon1, lon2, lat1, lat2, boxzoom[0], boxzoom[1]] |
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| 126 | N_Elements(Boxzoom) Eq 4:bte = [Boxzoom, vert1, vert2] |
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| 127 | N_Elements(Boxzoom) Eq 5:bte = [Boxzoom[0:3], 0, Boxzoom[4]] |
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| 128 | N_Elements(Boxzoom) Eq 6:bte = Boxzoom |
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| 129 | Else: return, report('Mauvaise Definition de Boxzoom') |
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| 130 | endcase |
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| 131 | if NOT keyword_set(nodomdef) then BEGIN |
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| 132 | savedbox = 1b |
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| 133 | saveboxparam, 'boxparam4moyenne.dat' |
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| 134 | domdef, bte, GRIDTYPE = vargrid, _extra = ex |
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| 135 | ENDIF |
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| 136 | ENDIF |
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[2] | 137 | ;--------------------------------------------------------------- |
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[142] | 138 | ; attribution of the mask and of longitude and latitude arrays... |
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[2] | 139 | ;--------------------------------------------------------------- |
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[25] | 140 | IF vargrid EQ 'W' THEN wdepth = 1 |
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| 141 | grille, mask, glam, gphi, gdep, nx, ny, nz, firstx, firsty, firstz, lastx, lasty, lastz, e1, e2, e3, WDEPTH = wdepth |
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[2] | 142 | ;------------------------------------------------------------ |
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| 143 | ;------------------------------------------------------------ |
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[142] | 144 | ; II) Case of the 1d array |
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[2] | 145 | ;------------------------------------------------------------ |
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| 146 | ;------------------------------------------------------------ |
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[25] | 147 | if dim EQ '1d' then BEGIN |
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| 148 | if n_elements(tab) NE nx*ny AND n_elements(tab) NE nx*ny*nz then BEGIN |
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| 149 | if keyword_set(savedbox) THEN restoreboxparam, 'boxparam4moyenne.dat' |
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| 150 | return, report('Probleme d''adequation entre les tailles du domaine et de la boxzoom.') |
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| 151 | ENDIF |
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| 152 | case 1 of |
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[142] | 153 | nx EQ 1 AND ny EQ 1:BEGIN ;vector following z |
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[25] | 154 | case n_elements(tab) of |
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| 155 | jpk:res = tab[firstz:lastz] |
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| 156 | nz:res = tab |
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| 157 | ELSE:BEGIN |
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| 158 | if keyword_set(savedbox) THEN restoreboxparam, 'boxparam4moyenne.dat' |
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| 159 | return, report('Probleme d''adequation entre les tailles du domaine et de la boxzoom.') |
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| 160 | END |
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| 161 | ENDCASE |
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| 162 | if dirz EQ 1 then BEGIN |
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| 163 | dim = '3d' |
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| 164 | taille = size(reform(res, nx, ny, nz)) |
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| 165 | ENDIF ELSE BEGIN |
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| 166 | if keyword_set(savedbox) THEN restoreboxparam, 'boxparam4moyenne.dat' |
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| 167 | return, res |
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| 168 | ENDELSE |
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| 169 | END |
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[142] | 170 | ny EQ 1:BEGIN ;vector following x |
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[25] | 171 | case n_elements(tab) of |
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| 172 | jpi:res = tab[firstx:lastx] |
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| 173 | nx:res = tab |
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| 174 | ELSE:BEGIN |
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| 175 | if keyword_set(savedbox) THEN restoreboxparam, 'boxparam4moyenne.dat' |
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| 176 | return, report('Probleme d''adequation entre les tailles du domaine et de la boxzoom.') |
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| 177 | END |
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| 178 | ENDCASE |
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| 179 | if dirx EQ 1 then BEGIN |
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| 180 | dim = '2d' |
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| 181 | taille = size(reform(res, nx, ny)) |
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| 182 | ENDIF ELSE BEGIN |
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| 183 | if keyword_set(savedbox) THEN restoreboxparam, 'boxparam4moyenne.dat' |
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| 184 | return, res |
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| 185 | ENDELSE |
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| 186 | END |
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[142] | 187 | nx EQ 1:BEGIN ;vector following y |
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[25] | 188 | case n_elements(tab) of |
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| 189 | jpj:res = tab[firsty:lasty] |
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| 190 | ny:res = tab |
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| 191 | ELSE:BEGIN |
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| 192 | if keyword_set(savedbox) THEN restoreboxparam, 'boxparam4moyenne.dat' |
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| 193 | return, report('Probleme d''adequation entre les tailles du domaine et de la boxzoom.') |
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| 194 | END |
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| 195 | ENDCASE |
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| 196 | if diry EQ 1 then BEGIN |
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| 197 | dim = '2d' |
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| 198 | taille = size(reform(res, nx, ny)) |
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| 199 | ENDIF ELSE BEGIN |
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| 200 | if keyword_set(savedbox) THEN restoreboxparam, 'boxparam4moyenne.dat' |
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| 201 | return, res |
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| 202 | ENDELSE |
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| 203 | END |
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| 204 | endcase |
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| 205 | endif |
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[2] | 206 | ;------------------------------------------------------------ |
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| 207 | ;------------------------------------------------------------ |
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[142] | 208 | ; II) Case of the 2d array |
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[2] | 209 | ;------------------------------------------------------------ |
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| 210 | ;------------------------------------------------------------ |
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[25] | 211 | if (dim eq '2d') then begin |
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[2] | 212 | ;--------------------------------------------------------------- |
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[142] | 213 | ; II.1) verification of the coherence of the array's size to average |
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| 214 | ; Verification of the coherence between the array's size and the domain defined by domdef |
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| 215 | ; The input array must have either the total domain's size (jpi,jpj) or this |
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| 216 | ; one of the reduced domain (nx,ny) |
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[2] | 217 | ;--------------------------------------------------------------- |
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[25] | 218 | case 1 of |
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| 219 | taille[1] eq jpi and taille[2] eq jpj: $ |
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| 220 | res = tab[firstx:lastx, firsty:lasty] |
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| 221 | taille[1] eq nx and taille[2] eq ny:res = tab |
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| 222 | else:BEGIN |
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| 223 | if keyword_set(savedbox) THEN restoreboxparam, 'boxparam4moyenne.dat' |
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| 224 | return, report('Probleme d''adequation entre les tailles du domaine nx*ny '+strtrim(nx, 1)+'*'+strtrim(ny, 1)+' et du tableau '+strtrim(taille[1], 1)+'*'+strtrim(taille[2], 1)) |
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| 225 | END |
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| 226 | ENDCASE |
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| 227 | if keyword_set(nan) NE 0 then BEGIN |
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[142] | 228 | if nan NE 1 then BEGIN ; If nan is not !values.f_nan |
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| 229 | ; we put it at !values.f_nan |
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[25] | 230 | if abs(nan) LT 1e6 then notanumber = where(res EQ nan) $ |
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| 231 | ELSE notanumber = where(abs(res) GT abs(nan)/10.) |
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| 232 | if notanumber[0] NE -1 then res[temporary(notanumber)] = !values.f_nan |
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[2] | 233 | ENDIF |
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[25] | 234 | ENDIF |
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[2] | 235 | ;--------------------------------------------------------------- |
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[142] | 236 | ; Comment : WE HAVE TO BE CAREFUL ABOUT CASES WHERE THE DIMENSION TO AVERAGE = 1, |
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| 237 | ; AND MAKE SURE THAT IT EXIST. THAT IS WHY WE USE reform(...,nx,ny,...) WHICH CAN |
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| 238 | ; LOOK USELESS AT THE BEGINNING |
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[2] | 239 | ;--------------------------------------------------------------- |
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[25] | 240 | if nx EQ 1 OR ny EQ 1 then BEGIN |
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| 241 | res = reform(res, nx, ny, /over) |
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| 242 | e1 = reform(e1, nx, ny, /over) |
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| 243 | e2 = reform(e2, nx, ny, /over) |
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| 244 | endif |
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| 245 | if nx EQ 1 OR ny EQ 1 OR nz EQ 1 THEN $ |
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| 246 | mask = reform(mask, nx, ny, nz, /over) |
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[2] | 247 | ;--------------------------------------------------------------- |
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[142] | 248 | ; II.3) Different types of average |
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[2] | 249 | ;--------------------------------------------------------------- |
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[25] | 250 | mask = mask[*, *, 0] |
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| 251 | if keyword_set(nan) NE 0 then msknan = finite(res) ELSE msknan = -1 |
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| 252 | case 1 of |
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| 253 | (dirx eq 1) and (diry eq 0) : begin |
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| 254 | e = e1*mask |
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| 255 | if keyword_set(integration) then divi = 1 $ |
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| 256 | else begin |
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| 257 | divi = e |
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| 258 | IF msknan[0] NE -1 THEN divi = temporary(divi)*msknan |
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| 259 | if ny EQ 1 then divi = reform(divi, nx, ny, /over) |
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| 260 | divi = total(divi, 1) |
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| 261 | endelse |
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| 262 | res = res*e |
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| 263 | if ny EQ 1 then res = reform(res, nx, ny, /over) |
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| 264 | res = total(res, 1, nan = nan)/(divi > 1.) |
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| 265 | if msknan[0] NE -1 then begin |
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| 266 | testnan = msknan*mask |
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| 267 | if ny EQ 1 then testnan = reform(testnan, nx, ny, /over) |
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| 268 | testnan = total(testnan, 1)+(total(mask, 1) EQ 0) |
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| 269 | endif |
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| 270 | end |
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| 271 | (dirx eq 0) and (diry eq 1) : begin |
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| 272 | e = e2*mask |
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| 273 | if keyword_set(integration) then divi = 1 $ |
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| 274 | else begin |
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| 275 | divi = e |
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| 276 | IF msknan[0] NE -1 THEN divi = temporary(divi)*msknan |
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| 277 | if ny EQ 1 then divi = reform(divi, nx, ny, /over) |
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| 278 | divi = total(divi, 2) |
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| 279 | endelse |
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| 280 | res = res*e |
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| 281 | if ny EQ 1 then res = reform(res, nx, ny, /over) |
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| 282 | res = total(res, 2, nan = nan)/(divi > 1.) |
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| 283 | if msknan[0] NE -1 then begin |
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| 284 | testnan = msknan*mask |
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| 285 | if ny EQ 1 then testnan = reform(testnan, nx, ny, /over) |
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| 286 | testnan = total(testnan, 2)+(total(mask, 2) EQ 0) |
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| 287 | endif |
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| 288 | end |
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| 289 | (dirx eq 1) and (diry eq 1) : begin |
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| 290 | if keyword_set(integration) then divi = 1 else BEGIN |
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| 291 | IF msknan[0] NE -1 THEN divi = total(e1*e2*mask*msknan) $ |
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| 292 | ELSE divi = total(e1*e2*mask) |
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| 293 | ENDELSE |
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| 294 | res = total(res*e1*e2*mask, nan = nan)/(divi > 1.) |
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| 295 | if msknan[0] NE -1 then begin |
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| 296 | testnan = msknan*mask |
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| 297 | testnan = total(testnan)+(total(mask) EQ 0) |
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| 298 | endif |
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| 299 | end |
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| 300 | endcase |
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| 301 | endif |
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[2] | 302 | ;------------------------------------------------------------ |
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| 303 | ;------------------------------------------------------------ |
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[142] | 304 | ; III) Case 3d arrays series (tab4d) |
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[2] | 305 | ;------------------------------------------------------------ |
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| 306 | ;------------------------------------------------------------ |
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[25] | 307 | if (dim eq '3d') then begin |
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[2] | 308 | ;--------------------------------------------------------------- |
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[142] | 309 | ; III.1) Verification of the coherence of the array to average size |
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| 310 | ; Verification of the coherence between the array's size and the domain |
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| 311 | ; defind by domdef |
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| 312 | ; The input array must have either the total domain size (jpi,jpj,jpk) |
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| 313 | ; or this one of the reduced domain (nx,ny,ny) |
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[2] | 314 | ;--------------------------------------------------------------- |
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[25] | 315 | case 1 of |
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| 316 | taille[1] eq jpi and taille[2] eq jpj and taille[3] eq jpk: $ |
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| 317 | res = tab[firstx:lastx, firsty:lasty, firstz:lastz] |
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| 318 | taille[1] eq jpi and taille[2] eq jpj and taille[3] eq nz: $ |
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| 319 | res = tab[firstx:lastx, firsty:lasty, *] |
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| 320 | taille[1] EQ nx and taille[2] eq ny and taille[3] eq nz :res = tab |
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| 321 | taille[1] EQ nx and taille[2] eq ny and taille[3] eq jpk : $ |
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| 322 | res = tab[*, *, firstz:lastz] |
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| 323 | else:BEGIN |
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| 324 | if keyword_set(savedbox) THEN restoreboxparam, 'boxparam4moyenne.dat' |
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| 325 | return, report('Probleme d''adequation entre les tailles du domaine nx*ny*nz '+strtrim(nx, 1)+'*'+strtrim(ny, 1)+'*'+strtrim(nz, 1)+' et du tableau '+strtrim(taille[1], 1)+'*'+strtrim(taille[2], 1)+'*'+strtrim(taille[3], 1)) |
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| 326 | END |
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| 327 | endcase |
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| 328 | if keyword_set(nan) NE 0 then BEGIN |
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[142] | 329 | if nan NE 1 then BEGIN ; if nan is not !values.f_nan |
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| 330 | ; we put it at !values.f_nan |
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[25] | 331 | if abs(nan) LT 1e6 then notanumber = where(res EQ nan) $ |
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| 332 | ELSE notanumber = where(abs(res) GT abs(nan)/10.) |
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| 333 | if notanumber[0] NE -1 then res[temporary(notanumber)] = !values.f_nan |
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[2] | 334 | ENDIF |
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[25] | 335 | ENDIF |
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[2] | 336 | ;--------------------------------------------------------------- |
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[142] | 337 | ; Comment : WE HAVE TO BE CAREFUL ABOUT CASES WHERE THE DIMENSION TO AVERAGE = 1, |
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| 338 | ; AND MAKE SURE THAT IT EXIST. THAT IS WHY WE USE reform(...,nx,ny,...) WHICH CAN |
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| 339 | ; LOOK USELESS AT THE BEGINNING |
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[2] | 340 | ;--------------------------------------------------------------- |
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[25] | 341 | if nx EQ 1 OR ny EQ 1 OR nz EQ 1 then BEGIN |
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| 342 | res = reform(res, nx, ny, nz, /over) |
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| 343 | e1 = reform(e1, nx, ny, /over) |
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| 344 | e2 = reform(e2, nx, ny, /over) |
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| 345 | endif |
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| 346 | if nx EQ 1 OR ny EQ 1 OR nz EQ 1 THEN $ |
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| 347 | mask = reform(mask, nx, ny, nz, /over) |
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| 348 | IF keyword_set(key_partialstep) THEN BEGIN |
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| 349 | ; the top of the ocean floor is |
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| 350 | IF vargrid EQ 'T' OR vargrid EQ 'W' THEN bottom = total(mask, 3) $ |
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| 351 | ELSE bottom = total(tmask[firstx:lastx, firsty:lasty, firstz:lastz], 3) |
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| 352 | ; we suppress columns with only ocean or land |
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| 353 | good = where(bottom NE 0 AND bottom NE nz) |
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| 354 | ; the bottom of the ocean in 3D index is: |
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| 355 | bottom = lindgen(nx*ny)+(temporary(bottom)-1L)*nx*ny |
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| 356 | IF good[0] NE -1 THEN bottom = bottom[good] $ |
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| 357 | ELSE bottom = -1 |
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| 358 | ENDIF ELSE bottom = -1 |
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[2] | 359 | ;--------------------------------------------------------------- |
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[142] | 360 | ; III.2) different average types |
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[2] | 361 | ;--------------------------------------------------------------- |
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[25] | 362 | if keyword_set(nan) NE 0 then msknan = finite(res) ELSE msknan = -1 |
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| 363 | case 1 of |
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| 364 | (dirx eq 1) and (diry eq 0) and (dirz eq 0) : begin |
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| 365 | e13 = e1[*]#replicate(1., nz) |
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| 366 | e13 = reform(e13, nx, ny, nz, /over) |
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| 367 | IF keyword_set(key_partialstep) AND bottom[0] NE -1 $ |
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| 368 | AND nx NE 1 THEN BEGIN |
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| 369 | IF msknan[0] EQ -1 THEN BEGIN |
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| 370 | msknan = replicate(1b, nx, ny, nz) |
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| 371 | nan = 1 |
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| 372 | endif |
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| 373 | msknan[bottom] = 0 |
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| 374 | res[bottom] = !values.f_nan |
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| 375 | ENDIF |
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| 376 | if keyword_set(integration) then divi = 1 else begin |
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| 377 | divi = e13*mask |
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| 378 | IF msknan[0] NE -1 THEN divi = temporary(divi)*msknan |
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| 379 | if nz EQ 1 then divi = reform(divi, nx, ny, nz, /over) |
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| 380 | divi = total(divi, 1) |
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| 381 | ENDELSE |
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| 382 | res = res*e13*mask |
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| 383 | if nz EQ 1 then res = reform(res, nx, ny, nz, /over) |
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| 384 | res = total(res, 1, nan = nan)/(divi > 1.) |
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| 385 | e13 = 1 |
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| 386 | if msknan[0] NE -1 then begin |
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| 387 | testnan = msknan*mask |
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| 388 | if nz EQ 1 then testnan = reform(testnan, nx, ny, nz, /over) |
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| 389 | testnan = total(testnan, 1)+(total(mask, 1) EQ 0) |
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| 390 | endif |
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| 391 | end |
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| 392 | (dirx eq 0) and (diry eq 1) and (dirz eq 0) : begin |
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| 393 | e23 = e2[*]#replicate(1., nz) |
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| 394 | e23 = reform(e23, nx, ny, nz, /over) |
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| 395 | IF keyword_set(key_partialstep) AND bottom[0] NE -1 $ |
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| 396 | AND ny NE 1 THEN BEGIN |
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| 397 | IF msknan[0] EQ -1 THEN BEGIN |
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| 398 | msknan = replicate(1b, nx, ny, nz) |
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| 399 | nan = 1 |
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| 400 | endif |
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| 401 | msknan[bottom] = 0 |
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| 402 | res[bottom] = !values.f_nan |
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| 403 | ENDIF |
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| 404 | if keyword_set(integration) then divi = 1 else begin |
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| 405 | divi = e23*mask |
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| 406 | IF msknan[0] NE -1 THEN divi = temporary(divi)*msknan |
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| 407 | if nz EQ 1 then divi = reform(divi, nx, ny, nz, /over) |
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| 408 | divi = total(divi, 2) |
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| 409 | ENDELSE |
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| 410 | res = res*e23*mask |
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| 411 | if nz EQ 1 then res = reform(res, nx, ny, nz, /over) |
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| 412 | res = total(res, 2, nan = nan)/(divi > 1.) |
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| 413 | e23 = 1 |
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| 414 | if msknan[0] NE -1 then begin |
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| 415 | testnan = msknan*mask |
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| 416 | if nz EQ 1 then testnan = reform(testnan, nx, ny, nz, /over) |
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| 417 | testnan = total(testnan, 2)+(total(mask, 2) EQ 0) |
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| 418 | endif |
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| 419 | end |
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| 420 | (dirx eq 0) and (diry eq 0) and (dirz eq 1) : begin |
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| 421 | e33 = replicate(1, 1.*nx*ny)#e3 |
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| 422 | e33 = reform(e33, nx, ny, nz, /over) |
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| 423 | IF keyword_set(key_partialstep) AND bottom[0] NE -1 THEN BEGIN |
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| 424 | IF keyword_set(wdepth) THEN $ |
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| 425 | e33[bottom] = (e3w_ps[firstx:lastx, firsty:lasty])[temporary(good)] $ |
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| 426 | ELSE e33[bottom] = (e3t_ps[firstx:lastx, firsty:lasty])[temporary(good)] |
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| 427 | ENDIF |
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| 428 | if keyword_set(integration) then divi = 1 else begin |
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| 429 | divi = e33*mask |
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| 430 | if msknan[0] NE -1 then divi = temporary(divi)*msknan |
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| 431 | if nz EQ 1 then divi = reform(divi, nx, ny, nz, /over) |
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| 432 | divi = total(divi, 3) |
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| 433 | ENDELSE |
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| 434 | res = res*e33*mask |
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| 435 | if nz EQ 1 then res = reform(res, nx, ny, nz, /over) |
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| 436 | res = total(res, 3, nan = nan)/(divi > 1.) |
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| 437 | e33 = 1 |
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| 438 | if msknan[0] NE -1 then begin |
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| 439 | testnan = msknan*mask |
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| 440 | if nz EQ 1 then testnan = reform(testnan, nx, ny, nz, /over) |
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| 441 | testnan = total(testnan, 3)+(total(mask, 3) EQ 0) |
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| 442 | endif |
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| 443 | end |
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| 444 | (dirx eq 1) and (diry eq 1) and (dirz eq 0) : begin |
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| 445 | e123 = (e1*e2)[*]#replicate(1., nz) |
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| 446 | e123 = reform(e123, nx, ny, nz, /over) |
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| 447 | IF keyword_set(key_partialstep) AND bottom[0] NE -1 $ |
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| 448 | AND nx*ny NE 1 THEN BEGIN |
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| 449 | IF msknan[0] EQ -1 THEN BEGIN |
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| 450 | msknan = replicate(1b, nx, ny, nz) |
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| 451 | nan = 1 |
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| 452 | endif |
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| 453 | msknan[bottom] = 0 |
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| 454 | res[bottom] = !values.f_nan |
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| 455 | ENDIF |
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| 456 | if keyword_set(integration) then divi = 1 else BEGIN |
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| 457 | divi = e123*mask |
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| 458 | IF msknan[0] NE -1 THEN divi = temporary(divi)*msknan |
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| 459 | if nz EQ 1 then divi = reform(divi, nx, ny, nz, /over) |
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| 460 | divi = total(total(divi, 1), 1) |
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| 461 | ENDELSE |
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| 462 | res = res*e123*mask |
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| 463 | if nz EQ 1 then res = reform(res, nx, ny, nz, /over) |
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| 464 | res = total(total(res, 1, nan = nan), 1, nan = nan) / (divi > 1.) |
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| 465 | e123 = 1 |
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| 466 | if msknan[0] NE -1 then begin |
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| 467 | testnan = msknan*mask |
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| 468 | if nz EQ 1 then testnan = reform(testnan, nx, ny, nz, /over) |
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| 469 | testnan = total(total(testnan, 1), 1)+(total(total(mask, 1), 1) EQ 0) |
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| 470 | endif |
---|
| 471 | end |
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| 472 | (dirx eq 1) and (diry eq 0) and (dirz eq 1) : begin |
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| 473 | e133 = e1[*]#e3 |
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| 474 | e133 = reform(e133, nx, ny, nz, /over) |
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| 475 | IF keyword_set(key_partialstep) AND bottom[0] NE -1 THEN BEGIN |
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| 476 | IF keyword_set(wdepth) THEN $ |
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| 477 | e133[bottom] = (e1*e3w_ps[firstx:lastx, firsty:lasty])[temporary(good)] $ |
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| 478 | ELSE e133[bottom] = (e1*e3t_ps[firstx:lastx, firsty:lasty])[temporary(good)] |
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| 479 | ENDIF |
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| 480 | if keyword_set(integration) then divi = 1 else BEGIN |
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| 481 | divi = e133*mask |
---|
| 482 | if msknan[0] NE -1 then divi = temporary(divi)*msknan |
---|
| 483 | if nz EQ 1 then divi = reform(divi, nx, ny, nz, /over) |
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| 484 | divi = total(total(divi, 1), 2) |
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| 485 | ENDELSE |
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| 486 | res = res*e133*mask |
---|
| 487 | if nz EQ 1 then res = reform(res, nx, ny, nz, /over) |
---|
| 488 | res = total(total(res, 1, nan = nan), 2, nan = nan) / (divi > 1.) |
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| 489 | e133 = 1 |
---|
| 490 | if msknan[0] NE -1 then begin |
---|
| 491 | testnan = msknan*mask |
---|
| 492 | if nz EQ 1 then testnan = reform(testnan, nx, ny, nz, /over) |
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| 493 | testnan = total(total(testnan, 1), 2)+(total(total(mask, 1), 2) EQ 0) |
---|
| 494 | endif |
---|
| 495 | end |
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| 496 | (dirx eq 0) and (diry eq 1) and (dirz eq 1) : begin |
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| 497 | e233 = e2[*]#e3 |
---|
| 498 | e233 = reform(e233, nx, ny, nz, /over) |
---|
| 499 | IF keyword_set(key_partialstep) AND bottom[0] NE -1 THEN BEGIN |
---|
| 500 | IF keyword_set(wdepth) THEN $ |
---|
| 501 | e233[bottom] = (e2*e3w_ps[firstx:lastx, firsty:lasty])[temporary(good)] $ |
---|
| 502 | ELSE e233[bottom] = (e2*e3t_ps[firstx:lastx, firsty:lasty])[temporary(good)] |
---|
| 503 | ENDIF |
---|
| 504 | if keyword_set(integration) then divi = 1 else BEGIN |
---|
| 505 | divi = e233*mask |
---|
| 506 | if msknan[0] NE -1 then divi = temporary(divi)*msknan |
---|
| 507 | if nz EQ 1 then divi = reform(divi, nx, ny, nz, /over) |
---|
| 508 | divi = total(total(divi, 2), 2) |
---|
| 509 | ENDELSE |
---|
| 510 | res = res*e233*mask |
---|
| 511 | if nz EQ 1 then res = reform(res, nx, ny, nz, /over) |
---|
| 512 | res = total(total(res, 2, nan = nan), 2, nan = nan) / (divi > 1.) |
---|
| 513 | e233 = 1 |
---|
| 514 | if msknan[0] NE -1 then begin |
---|
| 515 | testnan = msknan*mask |
---|
| 516 | if nz EQ 1 then testnan = reform(testnan, nx, ny, nz, /over) |
---|
| 517 | testnan = total(total(testnan, 2), 2)+(total(total(mask, 2), 2) EQ 0) |
---|
| 518 | endif |
---|
| 519 | end |
---|
| 520 | (dirx eq 1) and (diry eq 1) and (dirz eq 1) : begin |
---|
| 521 | e1233 = (e1*e2)[*]#e3 |
---|
| 522 | e1233 = reform(e1233, nx, ny, nz, /over) |
---|
| 523 | IF keyword_set(key_partialstep) AND bottom[0] NE -1 THEN BEGIN |
---|
| 524 | IF keyword_set(wdepth) THEN $ |
---|
| 525 | e1233[bottom] = (e1*e2*e3w_ps[firstx:lastx, firsty:lasty])[temporary(good)] $ |
---|
| 526 | ELSE e1233[bottom] = (e1*e2*e3t_ps[firstx:lastx, firsty:lasty])[temporary(good)] |
---|
| 527 | ENDIF |
---|
| 528 | if keyword_set(integration) then divi = 1 else BEGIN |
---|
| 529 | if msknan[0] NE -1 then divi = total(e1233*mask*msknan) $ |
---|
| 530 | ELSE divi = total(e1233*mask) |
---|
| 531 | ENDELSE |
---|
| 532 | res = total(res*e1233*mask, nan = nan) / (divi > 1.) |
---|
| 533 | e1233 = 1 |
---|
| 534 | if msknan[0] NE -1 then begin |
---|
| 535 | testnan = msknan*mask |
---|
| 536 | testnan = total(testnan)+(total(mask) EQ 0) |
---|
| 537 | endif |
---|
| 538 | end |
---|
| 539 | endcase |
---|
| 540 | endif |
---|
[2] | 541 | ;------------------------------------------------------------ |
---|
| 542 | ;------------------------------------------------------------ |
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[142] | 543 | ;IV ) finishing |
---|
[2] | 544 | ;------------------------------------------------------------ |
---|
| 545 | ;------------------------------------------------------------ |
---|
[142] | 546 | ; IV.1) We mask land by a value equal to 1.e+20 |
---|
[2] | 547 | ;------------------------------------------------------------ |
---|
[25] | 548 | valmask = 1e+20 |
---|
| 549 | terre = where(divi EQ 0) |
---|
| 550 | IF terre[0] NE -1 THEN BEGIN |
---|
[114] | 551 | res[terre] = 1e+20 |
---|
[25] | 552 | ENDIF |
---|
[2] | 553 | ;------------------------------------------------------------ |
---|
[142] | 554 | ; IV.2) We replace, when nan equal 1, !values.f_nan by nan |
---|
[2] | 555 | ;------------------------------------------------------------ |
---|
[25] | 556 | if keyword_set(nan) NE 0 then BEGIN |
---|
| 557 | puttonan = where(testnan EQ 0) |
---|
| 558 | if puttonan[0] NE -1 then res[puttonan] = !values.f_nan |
---|
| 559 | if nan NE 1 then BEGIN |
---|
| 560 | notanumber = where(finite(res) eq 0) |
---|
| 561 | if notanumber[0] NE -1 then res[notanumber] = nan |
---|
| 562 | ENDIF |
---|
| 563 | ENDIF |
---|
[2] | 564 | ;------------------------------------------------------------ |
---|
[142] | 565 | ; IV.3) We replace in the domain whch was defined at the entry of average |
---|
[2] | 566 | ;------------------------------------------------------------ |
---|
[25] | 567 | if keyword_set(savedbox) THEN restoreboxparam, 'boxparam4moyenne.dat' |
---|
[2] | 568 | ;------------------------------------------------------------ |
---|
[25] | 569 | if keyword_set(key_performance) THEN print, 'temps moyenne', systime(1)-tempsun |
---|
| 570 | return, res |
---|
[2] | 571 | ;------------------------------------------------------------ |
---|
| 572 | ;------------------------------------------------------------ |
---|
| 573 | end |
---|