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module grid_atob |
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|
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! From grid_atob.F,v 1.1.1.1 2004/05/19 12:53:05 |
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|
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IMPLICIT none |
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|
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contains |
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|
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real function grille_m(xdata, ydata, entree, x, y) |
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|
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!======================================================================= |
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! Z. X. Li (le 1 avril 1994) (voir aussi A. Harzallah et L. Fairhead) |
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|
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! Méthode naïve pour transformer un champ d'une grille fine à une |
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! grille grossière. Je considère que les nouveaux points occupent |
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! une zone adjacente qui comprend un ou plusieurs anciens points |
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|
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! Aucune pondération n'est considérée (voir grille_p) |
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|
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! (c) |
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! ----d----- |
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! | . . . .| |
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! | | |
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! (b)a . * . .b(a) |
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! | | |
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! | . . . .| |
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! ----c----- |
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! (d) |
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!======================================================================= |
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! INPUT: |
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! imdep, jmdep: dimensions X et Y pour depart |
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! xdata, ydata: coordonnees X et Y pour depart |
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! entree: champ d'entree a transformer |
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! OUTPUT: |
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! imar, jmar: dimensions X et Y d'arrivee |
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! x, y: coordonnees X et Y d'arrivee |
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! grille_m: champ de sortie deja transforme |
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!======================================================================= |
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|
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use numer_rec, only: assert_eq |
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|
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REAL, intent(in):: xdata(:),ydata(:) |
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REAL, intent(in):: entree(:, :) |
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REAL, intent(in):: x(:), y(:) |
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|
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dimension grille_m(size(x), size(y)) |
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|
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! Variables local to the procedure: |
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INTEGER imdep, jmdep, imar, jmar |
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INTEGER i, j, ii, jj |
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REAL a(2200),b(2200),c(1100),d(1100) |
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REAL number(2200,1100) |
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REAL distans(2200*1100) |
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INTEGER i_proche, j_proche, ij_proche |
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REAL zzmin |
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|
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!------------------------- |
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|
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print *, "Call sequence information: grille_m" |
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|
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imdep = assert_eq(size(xdata), size(entree, 1), "grille_m") |
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jmdep = assert_eq(size(ydata), size(entree, 2), "grille_m") |
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imar = size(x) |
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jmar = size(y) |
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|
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IF (imar.GT.2200 .OR. jmar.GT.1100) THEN |
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PRINT*, 'imar ou jmar trop grand', imar, jmar |
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STOP 1 |
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ENDIF |
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|
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! Calculer les limites des zones des nouveaux points |
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|
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a(1) = x(1) - (x(2)-x(1))/2.0 |
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b(1) = (x(1)+x(2))/2.0 |
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DO i = 2, imar-1 |
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a(i) = b(i-1) |
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b(i) = (x(i)+x(i+1))/2.0 |
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ENDDO |
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a(imar) = b(imar-1) |
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b(imar) = x(imar) + (x(imar)-x(imar-1))/2.0 |
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|
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c(1) = y(1) - (y(2)-y(1))/2.0 |
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d(1) = (y(1)+y(2))/2.0 |
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DO j = 2, jmar-1 |
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c(j) = d(j-1) |
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d(j) = (y(j)+y(j+1))/2.0 |
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ENDDO |
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c(jmar) = d(jmar-1) |
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d(jmar) = y(jmar) + (y(jmar)-y(jmar-1))/2.0 |
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|
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DO i = 1, imar |
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DO j = 1, jmar |
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number(i,j) = 0.0 |
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grille_m(i,j) = 0.0 |
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ENDDO |
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ENDDO |
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|
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! Determiner la zone sur laquelle chaque ancien point se trouve |
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|
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DO ii = 1, imar |
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DO jj = 1, jmar |
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DO i = 1, imdep |
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IF( ( xdata(i)-a(ii) >= 1.e-5.AND.xdata(i)-b(ii) <= 1.e-5 ).OR. & |
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(xdata(i)-a(ii) <= 1.e-5.AND.xdata(i)-b(ii) >= 1.e-5 ) ) & |
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THEN |
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DO j = 1, jmdep |
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IF((ydata(j)-c(jj) >= 1.e-5.AND.ydata(j)-d(jj) <= 1.e-5 ) & |
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.OR. (ydata(j)-c(jj) <= 1.e-5 .AND. & |
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ydata(j)-d(jj) >= 1.e-5)) THEN |
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number(ii,jj) = number(ii,jj) + 1.0 |
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grille_m(ii,jj) = grille_m(ii,jj) + entree(i,j) |
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ENDIF |
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ENDDO |
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ENDIF |
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ENDDO |
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ENDDO |
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ENDDO |
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|
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! Si aucun ancien point ne tombe sur une zone, c'est un probleme |
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|
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DO i = 1, imar |
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DO j = 1, jmar |
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IF (number(i,j) .GT. 0.001) THEN |
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grille_m(i,j) = grille_m(i,j) / number(i,j) |
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ELSE |
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PRINT*, 'probleme,i,j=', i,j |
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CALL dist_sphe(x(i),y(j),xdata,ydata,imdep,jmdep,distans) |
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ij_proche = 1 |
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zzmin = distans(ij_proche) |
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DO ii = 2, imdep*jmdep |
131 |
IF (distans(ii).LT.zzmin) THEN |
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zzmin = distans(ii) |
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ij_proche = ii |
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ENDIF |
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ENDDO |
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j_proche = (ij_proche-1)/imdep + 1 |
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i_proche = ij_proche - (j_proche-1)*imdep |
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PRINT*, "solution:", ij_proche, i_proche, j_proche |
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grille_m(i,j) = entree(i_proche,j_proche) |
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ENDIF |
141 |
ENDDO |
142 |
ENDDO |
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|
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END function grille_m |
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|
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SUBROUTINE grille_p(imdep, jmdep, xdata, ydata, entree, & |
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imar, jmar, x, y, sortie) |
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!======================================================================= |
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! z.x.li (le 1 avril 1994) (voir aussi A. Harzallah et L. Fairhead) |
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|
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! Methode naive pour transformer un champ d'une grille fine a une |
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! grille grossiere. Je considere que les nouveaux points occupent |
153 |
! une zone adjacente qui comprend un ou plusieurs anciens points |
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|
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! Consideration de la distance des points (voir grille_m) |
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|
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! (c) |
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! ----d----- |
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! | . . . .| |
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! | | |
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! (b)a . * . .b(a) |
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! | | |
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! | . . . .| |
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! ----c----- |
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! (d) |
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!======================================================================= |
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! INPUT: |
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! imdep, jmdep: dimensions X et Y pour depart |
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! xdata, ydata: coordonnees X et Y pour depart |
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! entree: champ d'entree a transformer |
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! OUTPUT: |
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! imar, jmar: dimensions X et Y d'arrivee |
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! x, y: coordonnees X et Y d'arrivee |
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! sortie: champ de sortie deja transforme |
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!======================================================================= |
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|
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INTEGER imdep, jmdep |
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REAL xdata(imdep),ydata(jmdep) |
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REAL entree(imdep,jmdep) |
180 |
|
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INTEGER imar, jmar |
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REAL x(imar),y(jmar) |
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REAL sortie(imar,jmar) |
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|
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INTEGER i, j, ii, jj |
186 |
REAL a(400),b(400),c(200),d(200) |
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REAL number(400,200) |
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INTEGER indx(400,200), indy(400,200) |
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REAL dist(400,200), distsom(400,200) |
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|
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IF (imar.GT.400 .OR. jmar.GT.200) THEN |
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PRINT*, 'imar ou jmar trop grand', imar, jmar |
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STOP 1 |
194 |
ENDIF |
195 |
|
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IF (imdep.GT.400 .OR. jmdep.GT.200) THEN |
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PRINT*, 'imdep ou jmdep trop grand', imdep, jmdep |
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STOP 1 |
199 |
ENDIF |
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|
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! calculer les bords a et b de la nouvelle grille |
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|
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a(1) = x(1) - (x(2)-x(1))/2.0 |
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b(1) = (x(1)+x(2))/2.0 |
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DO i = 2, imar-1 |
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a(i) = b(i-1) |
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b(i) = (x(i)+x(i+1))/2.0 |
208 |
ENDDO |
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a(imar) = b(imar-1) |
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b(imar) = x(imar) + (x(imar)-x(imar-1))/2.0 |
211 |
|
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! calculer les bords c et d de la nouvelle grille |
213 |
|
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c(1) = y(1) - (y(2)-y(1))/2.0 |
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d(1) = (y(1)+y(2))/2.0 |
216 |
DO j = 2, jmar-1 |
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c(j) = d(j-1) |
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d(j) = (y(j)+y(j+1))/2.0 |
219 |
ENDDO |
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c(jmar) = d(jmar-1) |
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d(jmar) = y(jmar) + (y(jmar)-y(jmar-1))/2.0 |
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|
223 |
! trouver les indices (indx,indy) de la nouvelle grille sur laquelle |
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! un point de l'ancienne grille est tombe. |
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|
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! ..... Modif P. Le Van ( 23/08/95 ) .... |
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|
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DO ii = 1, imar |
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DO jj = 1, jmar |
230 |
DO i = 1, imdep |
231 |
IF( ( xdata(i)-a(ii) >= 1.e-5.AND.xdata(i)-b(ii) <= 1.e-5 ).OR. & |
232 |
( xdata(i)-a(ii) <= 1.e-5.AND.xdata(i)-b(ii) >= 1.e-5 ) ) & |
233 |
THEN |
234 |
DO j = 1, jmdep |
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IF( (ydata(j)-c(jj) >= 1.e-5.AND.ydata(j)-d(jj) <= 1.e-5 ).OR. & |
236 |
( ydata(j)-c(jj) <= 1.e-5.AND.ydata(j)-d(jj) >= 1.e-5 ) ) & |
237 |
THEN |
238 |
indx(i,j) = ii |
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indy(i,j) = jj |
240 |
ENDIF |
241 |
ENDDO |
242 |
ENDIF |
243 |
ENDDO |
244 |
ENDDO |
245 |
ENDDO |
246 |
|
247 |
! faire une verification |
248 |
|
249 |
DO i = 1, imdep |
250 |
DO j = 1, jmdep |
251 |
IF (indx(i,j).GT.imar .OR. indy(i,j).GT.jmar) THEN |
252 |
PRINT*, 'Probleme grave,i,j,indx,indy=', & |
253 |
i,j,indx(i,j),indy(i,j) |
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stop 1 |
255 |
ENDIF |
256 |
ENDDO |
257 |
ENDDO |
258 |
|
259 |
! calculer la distance des anciens points avec le nouveau point, |
260 |
! on prend ensuite une sorte d'inverse pour ponderation. |
261 |
|
262 |
DO i = 1, imar |
263 |
DO j = 1, jmar |
264 |
number(i,j) = 0.0 |
265 |
distsom(i,j) = 0.0 |
266 |
ENDDO |
267 |
ENDDO |
268 |
DO i = 1, imdep |
269 |
DO j = 1, jmdep |
270 |
dist(i,j) = SQRT ( (xdata(i)-x(indx(i,j)))**2 & |
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+(ydata(j)-y(indy(i,j)))**2 ) |
272 |
distsom(indx(i,j),indy(i,j)) = distsom(indx(i,j),indy(i,j)) & |
273 |
+ dist(i,j) |
274 |
number(indx(i,j),indy(i,j)) = number(indx(i,j),indy(i,j)) +1. |
275 |
ENDDO |
276 |
ENDDO |
277 |
DO i = 1, imdep |
278 |
DO j = 1, jmdep |
279 |
dist(i,j) = 1.0 - dist(i,j)/distsom(indx(i,j),indy(i,j)) |
280 |
ENDDO |
281 |
ENDDO |
282 |
|
283 |
DO i = 1, imar |
284 |
DO j = 1, jmar |
285 |
number(i,j) = 0.0 |
286 |
sortie(i,j) = 0.0 |
287 |
ENDDO |
288 |
ENDDO |
289 |
DO i = 1, imdep |
290 |
DO j = 1, jmdep |
291 |
sortie(indx(i,j),indy(i,j)) = sortie(indx(i,j),indy(i,j)) & |
292 |
+ entree(i,j) * dist(i,j) |
293 |
number(indx(i,j),indy(i,j)) = number(indx(i,j),indy(i,j)) & |
294 |
+ dist(i,j) |
295 |
ENDDO |
296 |
ENDDO |
297 |
DO i = 1, imar |
298 |
DO j = 1, jmar |
299 |
IF (number(i,j) .GT. 0.001) THEN |
300 |
sortie(i,j) = sortie(i,j) / number(i,j) |
301 |
ELSE |
302 |
PRINT*, 'probleme,i,j=', i,j |
303 |
STOP 1 |
304 |
ENDIF |
305 |
ENDDO |
306 |
ENDDO |
307 |
|
308 |
RETURN |
309 |
END SUBROUTINE grille_p |
310 |
|
311 |
!****************************************************************** |
312 |
|
313 |
SUBROUTINE mask_c_o(imdep, jmdep, xdata, ydata, relief, & |
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imar, jmar, x, y, mask) |
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!======================================================================= |
316 |
! z.x.li (le 1 avril 1994): A partir du champ de relief, on fabrique |
317 |
! un champ indicateur (masque) terre/ocean |
318 |
! terre:1; ocean:0 |
319 |
|
320 |
! Methode naive (voir grille_m) |
321 |
!======================================================================= |
322 |
|
323 |
INTEGER imdep, jmdep |
324 |
REAL xdata(imdep),ydata(jmdep) |
325 |
REAL relief(imdep,jmdep) |
326 |
|
327 |
INTEGER imar, jmar |
328 |
REAL x(imar),y(jmar) |
329 |
REAL mask(imar,jmar) |
330 |
|
331 |
INTEGER i, j, ii, jj |
332 |
REAL a(2200),b(2200),c(1100),d(1100) |
333 |
REAL num_tot(2200,1100), num_oce(2200,1100) |
334 |
|
335 |
IF (imar.GT.2200 .OR. jmar.GT.1100) THEN |
336 |
PRINT*, 'imar ou jmar trop grand', imar, jmar |
337 |
STOP 1 |
338 |
ENDIF |
339 |
|
340 |
a(1) = x(1) - (x(2)-x(1))/2.0 |
341 |
b(1) = (x(1)+x(2))/2.0 |
342 |
DO i = 2, imar-1 |
343 |
a(i) = b(i-1) |
344 |
b(i) = (x(i)+x(i+1))/2.0 |
345 |
ENDDO |
346 |
a(imar) = b(imar-1) |
347 |
b(imar) = x(imar) + (x(imar)-x(imar-1))/2.0 |
348 |
|
349 |
c(1) = y(1) - (y(2)-y(1))/2.0 |
350 |
d(1) = (y(1)+y(2))/2.0 |
351 |
DO j = 2, jmar-1 |
352 |
c(j) = d(j-1) |
353 |
d(j) = (y(j)+y(j+1))/2.0 |
354 |
ENDDO |
355 |
c(jmar) = d(jmar-1) |
356 |
d(jmar) = y(jmar) + (y(jmar)-y(jmar-1))/2.0 |
357 |
|
358 |
DO i = 1, imar |
359 |
DO j = 1, jmar |
360 |
num_oce(i,j) = 0.0 |
361 |
num_tot(i,j) = 0.0 |
362 |
ENDDO |
363 |
ENDDO |
364 |
|
365 |
! ..... Modif P. Le Van ( 23/08/95 ) .... |
366 |
|
367 |
DO ii = 1, imar |
368 |
DO jj = 1, jmar |
369 |
DO i = 1, imdep |
370 |
IF( ( xdata(i)-a(ii) >= 1.e-5.AND.xdata(i)-b(ii) <= 1.e-5 ).OR. & |
371 |
( xdata(i)-a(ii) <= 1.e-5.AND.xdata(i)-b(ii) >= 1.e-5 ) ) & |
372 |
THEN |
373 |
DO j = 1, jmdep |
374 |
IF( (ydata(j)-c(jj) >= 1.e-5.AND.ydata(j)-d(jj) <= 1.e-5 ).OR. & |
375 |
( ydata(j)-c(jj) <= 1.e-5.AND.ydata(j)-d(jj) >= 1.e-5 ) ) & |
376 |
THEN |
377 |
num_tot(ii,jj) = num_tot(ii,jj) + 1.0 |
378 |
IF (.NOT. ( relief(i,j) - 0.9>= 1.e-5 ) ) & |
379 |
num_oce(ii,jj) = num_oce(ii,jj) + 1.0 |
380 |
ENDIF |
381 |
ENDDO |
382 |
ENDIF |
383 |
ENDDO |
384 |
ENDDO |
385 |
ENDDO |
386 |
|
387 |
|
388 |
DO i = 1, imar |
389 |
DO j = 1, jmar |
390 |
IF (num_tot(i,j) .GT. 0.001) THEN |
391 |
IF ( num_oce(i,j)/num_tot(i,j) - 0.5 >= 1.e-5 ) THEN |
392 |
mask(i,j) = 0. |
393 |
ELSE |
394 |
mask(i,j) = 1. |
395 |
ENDIF |
396 |
ELSE |
397 |
PRINT*, 'probleme,i,j=', i,j |
398 |
STOP 1 |
399 |
ENDIF |
400 |
ENDDO |
401 |
ENDDO |
402 |
|
403 |
RETURN |
404 |
END SUBROUTINE mask_c_o |
405 |
|
406 |
! ************************************* |
407 |
|
408 |
real function rugosite(xdata, ydata, entree, x, y, mask) |
409 |
|
410 |
! Z. X. Li (le 1 avril 1994): Transformer la longueur de rugosite d'une |
411 |
! grille fine a une grille grossiere. Sur l'ocean, on impose une valeur |
412 |
! fixe (0.001m). |
413 |
|
414 |
! Methode naive (voir grille_m) |
415 |
|
416 |
use numer_rec, only: assert_eq |
417 |
|
418 |
REAL, intent(in):: xdata(:), ydata(:), entree(:,:), x(:), y(:), mask(:,:) |
419 |
|
420 |
dimension rugosite(size(mask, 1), size(mask, 2)) |
421 |
|
422 |
! Variables local to the procedure: |
423 |
INTEGER imdep, jmdep |
424 |
INTEGER imar, jmar |
425 |
INTEGER i, j, ii, jj |
426 |
REAL a(400),b(400),c(400),d(400) |
427 |
REAL num_tot(400,400) |
428 |
REAL distans(400*400) |
429 |
INTEGER i_proche, j_proche, ij_proche |
430 |
REAL zzmin |
431 |
|
432 |
! -------------------- |
433 |
|
434 |
imdep = assert_eq(size(xdata), size(entree, 1), "rugosite") |
435 |
jmdep = assert_eq(size(ydata), size(entree, 2), "rugosite") |
436 |
imar = assert_eq(size(x), size(mask, 1), "rugosite") |
437 |
jmar = assert_eq(size(y), size(mask, 2), "rugosite") |
438 |
|
439 |
IF (imar.GT.400 .OR. jmar.GT.400) THEN |
440 |
PRINT*, 'imar ou jmar trop grand', imar, jmar |
441 |
STOP 1 |
442 |
ENDIF |
443 |
|
444 |
a(1) = x(1) - (x(2)-x(1))/2.0 |
445 |
b(1) = (x(1)+x(2))/2.0 |
446 |
DO i = 2, imar-1 |
447 |
a(i) = b(i-1) |
448 |
b(i) = (x(i)+x(i+1))/2.0 |
449 |
ENDDO |
450 |
a(imar) = b(imar-1) |
451 |
b(imar) = x(imar) + (x(imar)-x(imar-1))/2.0 |
452 |
|
453 |
c(1) = y(1) - (y(2)-y(1))/2.0 |
454 |
d(1) = (y(1)+y(2))/2.0 |
455 |
DO j = 2, jmar-1 |
456 |
c(j) = d(j-1) |
457 |
d(j) = (y(j)+y(j+1))/2.0 |
458 |
ENDDO |
459 |
c(jmar) = d(jmar-1) |
460 |
d(jmar) = y(jmar) + (y(jmar)-y(jmar-1))/2.0 |
461 |
|
462 |
DO i = 1, imar |
463 |
DO j = 1, jmar |
464 |
num_tot(i,j) = 0.0 |
465 |
rugosite(i,j) = 0.0 |
466 |
ENDDO |
467 |
ENDDO |
468 |
|
469 |
|
470 |
! ..... Modif P. Le Van ( 23/08/95 ) .... |
471 |
|
472 |
DO ii = 1, imar |
473 |
DO jj = 1, jmar |
474 |
DO i = 1, imdep |
475 |
IF( ( xdata(i)-a(ii) >= 1.e-5.AND.xdata(i)-b(ii) <= 1.e-5 ).OR. & |
476 |
( xdata(i)-a(ii) <= 1.e-5.AND.xdata(i)-b(ii) >= 1.e-5 ) ) & |
477 |
THEN |
478 |
DO j = 1, jmdep |
479 |
IF( (ydata(j)-c(jj) >= 1.e-5.AND.ydata(j)-d(jj) <= 1.e-5 ).OR. & |
480 |
( ydata(j)-c(jj) <= 1.e-5.AND.ydata(j)-d(jj) >= 1.e-5 ) ) & |
481 |
THEN |
482 |
rugosite(ii,jj) = rugosite(ii,jj) + LOG(entree(i,j)) |
483 |
num_tot(ii,jj) = num_tot(ii,jj) + 1.0 |
484 |
ENDIF |
485 |
ENDDO |
486 |
ENDIF |
487 |
ENDDO |
488 |
ENDDO |
489 |
ENDDO |
490 |
|
491 |
DO i = 1, imar |
492 |
DO j = 1, jmar |
493 |
IF (NINT(mask(i,j)).EQ.1) THEN |
494 |
IF (num_tot(i,j) .GT. 0.0) THEN |
495 |
rugosite(i,j) = rugosite(i,j) / num_tot(i,j) |
496 |
rugosite(i,j) = EXP(rugosite(i,j)) |
497 |
ELSE |
498 |
PRINT*, 'probleme,i,j=', i,j |
499 |
!cc STOP 1 |
500 |
CALL dist_sphe(x(i),y(j),xdata,ydata,imdep,jmdep,distans) |
501 |
ij_proche = 1 |
502 |
zzmin = distans(ij_proche) |
503 |
DO ii = 2, imdep*jmdep |
504 |
IF (distans(ii).LT.zzmin) THEN |
505 |
zzmin = distans(ii) |
506 |
ij_proche = ii |
507 |
ENDIF |
508 |
ENDDO |
509 |
j_proche = (ij_proche-1)/imdep + 1 |
510 |
i_proche = ij_proche - (j_proche-1)*imdep |
511 |
PRINT*, "solution:", ij_proche, i_proche, j_proche |
512 |
rugosite(i,j) = entree(i_proche,j_proche) |
513 |
ENDIF |
514 |
ELSE |
515 |
rugosite(i,j) = 0.001 |
516 |
ENDIF |
517 |
ENDDO |
518 |
ENDDO |
519 |
|
520 |
RETURN |
521 |
END function rugosite |
522 |
|
523 |
!************************************ |
524 |
|
525 |
real function sea_ice(xdata, ydata, glace01, x, y) |
526 |
|
527 |
!======================================================================= |
528 |
! z.x.li (le 1 avril 1994): Transformer un champ d'indicateur de la |
529 |
! glace (1, sinon 0) d'une grille fine a un champ de fraction de glace |
530 |
! (entre 0 et 1) dans une grille plus grossiere. |
531 |
|
532 |
! Methode naive (voir grille_m) |
533 |
!======================================================================= |
534 |
|
535 |
use numer_rec, only: assert_eq |
536 |
|
537 |
REAL, intent(in):: xdata(:),ydata(:) |
538 |
REAL, intent(in):: glace01(:,:) |
539 |
REAL, intent(in):: x(:),y(:) |
540 |
dimension sea_ice(size(x), size(y)) |
541 |
|
542 |
! Variables local to the procedure: |
543 |
INTEGER imdep, jmdep |
544 |
INTEGER imar, jmar |
545 |
INTEGER i, j, ii, jj |
546 |
REAL a(400),b(400),c(400),d(400) |
547 |
REAL num_tot(400,400), num_ice(400,400) |
548 |
REAL distans(400*400) |
549 |
INTEGER i_proche, j_proche, ij_proche |
550 |
REAL zzmin |
551 |
|
552 |
!------------------------------ |
553 |
|
554 |
imdep = assert_eq(size(xdata), size(glace01, 1), "sea_ice") |
555 |
jmdep = assert_eq(size(ydata), size(glace01, 2), "sea_ice") |
556 |
imar = size(x) |
557 |
jmar = size(y) |
558 |
|
559 |
IF (imar.GT.400 .OR. jmar.GT.400) THEN |
560 |
PRINT*, 'imar ou jmar trop grand', imar, jmar |
561 |
STOP 1 |
562 |
ENDIF |
563 |
|
564 |
a(1) = x(1) - (x(2)-x(1))/2.0 |
565 |
b(1) = (x(1)+x(2))/2.0 |
566 |
DO i = 2, imar-1 |
567 |
a(i) = b(i-1) |
568 |
b(i) = (x(i)+x(i+1))/2.0 |
569 |
ENDDO |
570 |
a(imar) = b(imar-1) |
571 |
b(imar) = x(imar) + (x(imar)-x(imar-1))/2.0 |
572 |
|
573 |
c(1) = y(1) - (y(2)-y(1))/2.0 |
574 |
d(1) = (y(1)+y(2))/2.0 |
575 |
DO j = 2, jmar-1 |
576 |
c(j) = d(j-1) |
577 |
d(j) = (y(j)+y(j+1))/2.0 |
578 |
ENDDO |
579 |
c(jmar) = d(jmar-1) |
580 |
d(jmar) = y(jmar) + (y(jmar)-y(jmar-1))/2.0 |
581 |
|
582 |
DO i = 1, imar |
583 |
DO j = 1, jmar |
584 |
num_ice(i,j) = 0.0 |
585 |
num_tot(i,j) = 0.0 |
586 |
ENDDO |
587 |
ENDDO |
588 |
|
589 |
|
590 |
! ..... Modif P. Le Van ( 23/08/95 ) .... |
591 |
|
592 |
DO ii = 1, imar |
593 |
DO jj = 1, jmar |
594 |
DO i = 1, imdep |
595 |
IF( ( xdata(i)-a(ii) >= 1.e-5.AND.xdata(i)-b(ii) <= 1.e-5 ).OR. & |
596 |
( xdata(i)-a(ii) <= 1.e-5.AND.xdata(i)-b(ii) >= 1.e-5 ) ) & |
597 |
THEN |
598 |
DO j = 1, jmdep |
599 |
IF( (ydata(j)-c(jj) >= 1.e-5.AND.ydata(j)-d(jj) <= 1.e-5 ).OR. & |
600 |
( ydata(j)-c(jj) <= 1.e-5.AND.ydata(j)-d(jj) >= 1.e-5 ) ) & |
601 |
THEN |
602 |
num_tot(ii,jj) = num_tot(ii,jj) + 1.0 |
603 |
IF (NINT(glace01(i,j)).EQ.1 ) & |
604 |
num_ice(ii,jj) = num_ice(ii,jj) + 1.0 |
605 |
ENDIF |
606 |
ENDDO |
607 |
ENDIF |
608 |
ENDDO |
609 |
ENDDO |
610 |
ENDDO |
611 |
|
612 |
|
613 |
DO i = 1, imar |
614 |
DO j = 1, jmar |
615 |
IF (num_tot(i,j) .GT. 0.001) THEN |
616 |
IF (num_ice(i,j).GT.0.001) THEN |
617 |
sea_ice(i,j) = num_ice(i,j) / num_tot(i,j) |
618 |
ELSE |
619 |
sea_ice(i,j) = 0.0 |
620 |
ENDIF |
621 |
ELSE |
622 |
PRINT*, 'probleme,i,j=', i,j |
623 |
!cc STOP 1 |
624 |
CALL dist_sphe(x(i),y(j),xdata,ydata,imdep,jmdep,distans) |
625 |
ij_proche = 1 |
626 |
zzmin = distans(ij_proche) |
627 |
DO ii = 2, imdep*jmdep |
628 |
IF (distans(ii).LT.zzmin) THEN |
629 |
zzmin = distans(ii) |
630 |
ij_proche = ii |
631 |
ENDIF |
632 |
ENDDO |
633 |
j_proche = (ij_proche-1)/imdep + 1 |
634 |
i_proche = ij_proche - (j_proche-1)*imdep |
635 |
PRINT*, "solution:", ij_proche, i_proche, j_proche |
636 |
IF (NINT(glace01(i_proche,j_proche)).EQ.1 ) THEN |
637 |
sea_ice(i,j) = 1.0 |
638 |
ELSE |
639 |
sea_ice(i,j) = 0.0 |
640 |
ENDIF |
641 |
ENDIF |
642 |
ENDDO |
643 |
ENDDO |
644 |
|
645 |
RETURN |
646 |
END function sea_ice |
647 |
|
648 |
!************************************* |
649 |
|
650 |
SUBROUTINE rugsoro(imrel, jmrel, xrel, yrel, relief, immod, jmmod, xmod, & |
651 |
ymod, rugs) |
652 |
!======================================================================= |
653 |
! Calculer la longueur de rugosite liee au relief en utilisant |
654 |
! l'ecart-type dans une maille de 1x1 |
655 |
!======================================================================= |
656 |
|
657 |
REAL zzmin |
658 |
|
659 |
REAL amin, AMAX |
660 |
|
661 |
INTEGER, intent(in):: imrel, jmrel |
662 |
REAL, intent(in):: xrel(imrel),yrel(jmrel) |
663 |
REAL, intent(in):: relief(imrel,jmrel) |
664 |
|
665 |
INTEGER, intent(in):: immod, jmmod |
666 |
REAL, intent(in):: xmod(immod),ymod(jmmod) |
667 |
REAL, intent(out):: rugs(immod,jmmod) |
668 |
|
669 |
INTEGER imtmp, jmtmp |
670 |
PARAMETER (imtmp=360,jmtmp=180) |
671 |
REAL xtmp(imtmp), ytmp(jmtmp) |
672 |
double precision cham1tmp(imtmp,jmtmp), cham2tmp(imtmp,jmtmp) |
673 |
REAL zzzz |
674 |
|
675 |
INTEGER i, j, ii, jj |
676 |
REAL a(2200),b(2200),c(1100),d(1100) |
677 |
REAL number(2200,1100) |
678 |
|
679 |
REAL distans(400*400) |
680 |
INTEGER i_proche, j_proche, ij_proche |
681 |
|
682 |
IF (immod.GT.2200 .OR. jmmod.GT.1100) THEN |
683 |
PRINT*, 'immod ou jmmod trop grand', immod, jmmod |
684 |
STOP 1 |
685 |
ENDIF |
686 |
|
687 |
! Calculs intermediares: |
688 |
|
689 |
xtmp(1) = -180.0 + 360.0/FLOAT(imtmp) / 2.0 |
690 |
DO i = 2, imtmp |
691 |
xtmp(i) = xtmp(i-1) + 360.0/FLOAT(imtmp) |
692 |
ENDDO |
693 |
DO i = 1, imtmp |
694 |
xtmp(i) = xtmp(i) /180.0 * 4.0*ATAN(1.0) |
695 |
ENDDO |
696 |
ytmp(1) = -90.0 + 180.0/FLOAT(jmtmp) / 2.0 |
697 |
DO j = 2, jmtmp |
698 |
ytmp(j) = ytmp(j-1) + 180.0/FLOAT(jmtmp) |
699 |
ENDDO |
700 |
DO j = 1, jmtmp |
701 |
ytmp(j) = ytmp(j) /180.0 * 4.0*ATAN(1.0) |
702 |
ENDDO |
703 |
|
704 |
a(1) = xtmp(1) - (xtmp(2)-xtmp(1))/2.0 |
705 |
b(1) = (xtmp(1)+xtmp(2))/2.0 |
706 |
DO i = 2, imtmp-1 |
707 |
a(i) = b(i-1) |
708 |
b(i) = (xtmp(i)+xtmp(i+1))/2.0 |
709 |
ENDDO |
710 |
a(imtmp) = b(imtmp-1) |
711 |
b(imtmp) = xtmp(imtmp) + (xtmp(imtmp)-xtmp(imtmp-1))/2.0 |
712 |
|
713 |
c(1) = ytmp(1) - (ytmp(2)-ytmp(1))/2.0 |
714 |
d(1) = (ytmp(1)+ytmp(2))/2.0 |
715 |
DO j = 2, jmtmp-1 |
716 |
c(j) = d(j-1) |
717 |
d(j) = (ytmp(j)+ytmp(j+1))/2.0 |
718 |
ENDDO |
719 |
c(jmtmp) = d(jmtmp-1) |
720 |
d(jmtmp) = ytmp(jmtmp) + (ytmp(jmtmp)-ytmp(jmtmp-1))/2.0 |
721 |
|
722 |
DO i = 1, imtmp |
723 |
DO j = 1, jmtmp |
724 |
number(i,j) = 0.0 |
725 |
cham1tmp(i,j) = 0.0 |
726 |
cham2tmp(i,j) = 0.0 |
727 |
ENDDO |
728 |
ENDDO |
729 |
|
730 |
|
731 |
! ..... Modif P. Le Van ( 23/08/95 ) .... |
732 |
|
733 |
DO ii = 1, imtmp |
734 |
DO jj = 1, jmtmp |
735 |
DO i = 1, imrel |
736 |
IF( ( xrel(i)-a(ii) >= 1.e-5.AND.xrel(i)-b(ii) <= 1.e-5 ).OR. & |
737 |
( xrel(i)-a(ii) <= 1.e-5.AND.xrel(i)-b(ii) >= 1.e-5 ) ) & |
738 |
THEN |
739 |
DO j = 1, jmrel |
740 |
IF ((yrel(j)-c(jj) >= 1.e-5.AND.yrel(j)-d(jj) <= 1.e-5 ) & |
741 |
.OR. (yrel(j)-c(jj) <= 1.e-5 .AND. & |
742 |
yrel(j)-d(jj) >= 1.e-5 ) ) & |
743 |
THEN |
744 |
number(ii,jj) = number(ii,jj) + 1.0 |
745 |
cham1tmp(ii,jj) = cham1tmp(ii,jj) + relief(i,j) |
746 |
cham2tmp(ii,jj) = cham2tmp(ii,jj) & |
747 |
+ relief(i,j)*relief(i,j) |
748 |
ENDIF |
749 |
ENDDO |
750 |
ENDIF |
751 |
ENDDO |
752 |
ENDDO |
753 |
ENDDO |
754 |
|
755 |
DO i = 1, imtmp |
756 |
DO j = 1, jmtmp |
757 |
IF (number(i,j) .GT. 0.001) THEN |
758 |
cham1tmp(i,j) = cham1tmp(i,j) / number(i,j) |
759 |
cham2tmp(i,j) = cham2tmp(i,j) / number(i,j) |
760 |
zzzz=cham2tmp(i,j)-cham1tmp(i,j)**2 |
761 |
if (zzzz .lt. 0.0) then |
762 |
if (zzzz .gt. -7.5) then |
763 |
zzzz = 0.0 |
764 |
print*,'Pb rugsoro, -7.5 < zzzz < 0, => zzz = 0.0' |
765 |
else |
766 |
stop 'Pb rugsoro, zzzz <-7.5' |
767 |
endif |
768 |
endif |
769 |
cham2tmp(i,j) = SQRT(zzzz) |
770 |
ELSE |
771 |
PRINT*, 'probleme,i,j=', i,j |
772 |
STOP 1 |
773 |
ENDIF |
774 |
ENDDO |
775 |
ENDDO |
776 |
|
777 |
amin = cham2tmp(1,1) |
778 |
AMAX = cham2tmp(1,1) |
779 |
DO j = 1, jmtmp |
780 |
DO i = 1, imtmp |
781 |
IF (cham2tmp(i,j).GT.AMAX) AMAX = cham2tmp(i,j) |
782 |
IF (cham2tmp(i,j).LT.amin) amin = cham2tmp(i,j) |
783 |
ENDDO |
784 |
ENDDO |
785 |
PRINT*, 'Ecart-type 1x1:', amin, AMAX |
786 |
|
787 |
|
788 |
a(1) = xmod(1) - (xmod(2)-xmod(1))/2.0 |
789 |
b(1) = (xmod(1)+xmod(2))/2.0 |
790 |
DO i = 2, immod-1 |
791 |
a(i) = b(i-1) |
792 |
b(i) = (xmod(i)+xmod(i+1))/2.0 |
793 |
ENDDO |
794 |
a(immod) = b(immod-1) |
795 |
b(immod) = xmod(immod) + (xmod(immod)-xmod(immod-1))/2.0 |
796 |
|
797 |
c(1) = ymod(1) - (ymod(2)-ymod(1))/2.0 |
798 |
d(1) = (ymod(1)+ymod(2))/2.0 |
799 |
DO j = 2, jmmod-1 |
800 |
c(j) = d(j-1) |
801 |
d(j) = (ymod(j)+ymod(j+1))/2.0 |
802 |
ENDDO |
803 |
c(jmmod) = d(jmmod-1) |
804 |
d(jmmod) = ymod(jmmod) + (ymod(jmmod)-ymod(jmmod-1))/2.0 |
805 |
|
806 |
DO i = 1, immod |
807 |
DO j = 1, jmmod |
808 |
number(i,j) = 0.0 |
809 |
rugs(i,j) = 0.0 |
810 |
ENDDO |
811 |
ENDDO |
812 |
|
813 |
|
814 |
! ..... Modif P. Le Van ( 23/08/95 ) .... |
815 |
|
816 |
DO ii = 1, immod |
817 |
DO jj = 1, jmmod |
818 |
DO i = 1, imtmp |
819 |
IF( ( xtmp(i)-a(ii) >= 1.e-5.AND.xtmp(i)-b(ii) <= 1.e-5 ).OR. & |
820 |
( xtmp(i)-a(ii) <= 1.e-5.AND.xtmp(i)-b(ii) >= 1.e-5 ) ) & |
821 |
THEN |
822 |
DO j = 1, jmtmp |
823 |
IF ((ytmp(j) - c(jj) >= 1.e-5 & |
824 |
.AND. ytmp(j) - d(jj) <= 1.e-5) .OR. & |
825 |
(ytmp(j) - c(jj) <= 1.e-5 & |
826 |
.AND. ytmp(j) - d(jj) >= 1.e-5)) & |
827 |
THEN |
828 |
number(ii,jj) = number(ii,jj) + 1.0 |
829 |
rugs(ii,jj) = rugs(ii,jj) & |
830 |
+ LOG(MAX(0.001d0,cham2tmp(i,j))) |
831 |
ENDIF |
832 |
ENDDO |
833 |
ENDIF |
834 |
ENDDO |
835 |
ENDDO |
836 |
ENDDO |
837 |
|
838 |
DO i = 1, immod |
839 |
DO j = 1, jmmod |
840 |
IF (number(i,j) .GT. 0.001) THEN |
841 |
rugs(i,j) = rugs(i,j) / number(i,j) |
842 |
rugs(i,j) = EXP(rugs(i,j)) |
843 |
ELSE |
844 |
PRINT*, 'probleme,i,j=', i,j |
845 |
CALL dist_sphe(xmod(i),ymod(j),xtmp,ytmp,imtmp,jmtmp,distans) |
846 |
ij_proche = 1 |
847 |
zzmin = distans(ij_proche) |
848 |
DO ii = 2, imtmp*jmtmp |
849 |
IF (distans(ii).LT.zzmin) THEN |
850 |
zzmin = distans(ii) |
851 |
ij_proche = ii |
852 |
ENDIF |
853 |
ENDDO |
854 |
j_proche = (ij_proche-1)/imtmp + 1 |
855 |
i_proche = ij_proche - (j_proche-1)*imtmp |
856 |
PRINT*, "solution:", ij_proche, i_proche, j_proche |
857 |
rugs(i,j) = LOG(MAX(0.001d0,cham2tmp(i_proche,j_proche))) |
858 |
ENDIF |
859 |
ENDDO |
860 |
ENDDO |
861 |
|
862 |
amin = rugs(1,1) |
863 |
AMAX = rugs(1,1) |
864 |
DO j = 1, jmmod |
865 |
DO i = 1, immod |
866 |
IF (rugs(i,j).GT.AMAX) AMAX = rugs(i,j) |
867 |
IF (rugs(i,j).LT.amin) amin = rugs(i,j) |
868 |
ENDDO |
869 |
ENDDO |
870 |
PRINT*, 'Ecart-type du modele:', amin, AMAX |
871 |
|
872 |
DO j = 1, jmmod |
873 |
DO i = 1, immod |
874 |
rugs(i,j) = rugs(i,j) / AMAX * 20.0 |
875 |
ENDDO |
876 |
ENDDO |
877 |
|
878 |
amin = rugs(1,1) |
879 |
AMAX = rugs(1,1) |
880 |
DO j = 1, jmmod |
881 |
DO i = 1, immod |
882 |
IF (rugs(i,j).GT.AMAX) AMAX = rugs(i,j) |
883 |
IF (rugs(i,j).LT.amin) amin = rugs(i,j) |
884 |
ENDDO |
885 |
ENDDO |
886 |
PRINT*, 'Longueur de rugosite du modele:', amin, AMAX |
887 |
|
888 |
END SUBROUTINE rugsoro |
889 |
! |
890 |
SUBROUTINE dist_sphe(rf_lon,rf_lat,rlon,rlat,im,jm,distance) |
891 |
|
892 |
! Auteur: Laurent Li (le 30 decembre 1996) |
893 |
|
894 |
! Ce programme calcule la distance minimale (selon le grand cercle) |
895 |
! entre deux points sur la terre |
896 |
|
897 |
INTEGER, intent(in):: im, jm ! dimensions |
898 |
REAL, intent(in):: rf_lon ! longitude du point de reference (degres) |
899 |
REAL, intent(in):: rf_lat ! latitude du point de reference (degres) |
900 |
REAL, intent(in):: rlon(im), rlat(jm) ! longitude et latitude des points |
901 |
|
902 |
REAL, intent(out):: distance(im,jm) ! distances en metre |
903 |
|
904 |
REAL rlon1, rlat1 |
905 |
REAL rlon2, rlat2 |
906 |
REAL dist |
907 |
REAL pa, pb, p, pi |
908 |
|
909 |
REAL radius |
910 |
PARAMETER (radius=6371229.) |
911 |
integer i, j |
912 |
|
913 |
pi = 4.0 * ATAN(1.0) |
914 |
|
915 |
DO j = 1, jm |
916 |
DO i = 1, im |
917 |
|
918 |
rlon1=rf_lon |
919 |
rlat1=rf_lat |
920 |
rlon2=rlon(i) |
921 |
rlat2=rlat(j) |
922 |
pa = pi/2.0 - rlat1*pi/180.0 ! dist. entre pole n et point a |
923 |
pb = pi/2.0 - rlat2*pi/180.0 ! dist. entre pole n et point b |
924 |
p = (rlon1-rlon2)*pi/180.0 ! angle entre a et b (leurs meridiens) |
925 |
|
926 |
dist = ACOS( COS(pa)*COS(pb) + SIN(pa)*SIN(pb)*COS(p)) |
927 |
dist = radius * dist |
928 |
distance(i,j) = dist |
929 |
|
930 |
end DO |
931 |
end DO |
932 |
|
933 |
END SUBROUTINE dist_sphe |
934 |
|
935 |
end module grid_atob |