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! |
module fxhyp_m |
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! $Header: /home/cvsroot/LMDZ4/libf/dyn3d/fxhyp.F,v 1.2 2005/06/03 09:11:32 fairhead Exp $ |
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IMPLICIT NONE |
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c |
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contains |
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SUBROUTINE fxhyp ( xzoomdeg,grossism,dzooma,tau , |
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, rlonm025,xprimm025,rlonv,xprimv,rlonu,xprimu,rlonp025,xprimp025, |
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, champmin,champmax ) |
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c Auteur : P. Le Van |
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use dimens_m |
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use paramet_m |
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IMPLICIT NONE |
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c Calcule les longitudes et derivees dans la grille du GCM pour une |
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c fonction f(x) a tangente hyperbolique . |
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c |
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c grossism etant le grossissement ( = 2 si 2 fois, = 3 si 3 fois,etc.) |
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c dzoom etant la distance totale de la zone du zoom |
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c tau la raideur de la transition de l'interieur a l'exterieur du zoom |
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c |
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c On doit avoir grossism x dzoom < pi ( radians ) , en longitude. |
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c ******************************************************************** |
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INTEGER nmax, nmax2 |
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PARAMETER ( nmax = 30000, nmax2 = 2*nmax ) |
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c |
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LOGICAL scal180 |
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PARAMETER ( scal180 = .TRUE. ) |
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c scal180 = .TRUE. si on veut avoir le premier point scalaire pour |
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c une grille reguliere ( grossism = 1.,tau=0.,clon=0. ) a -180. degres. |
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c sinon scal180 = .FALSE. |
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c ...... arguments d'entree ....... |
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c |
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REAL xzoomdeg,dzooma,tau,grossism |
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c ...... arguments de sortie ...... |
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REAL rlonm025(iip1),xprimm025(iip1),rlonv(iip1),xprimv(iip1), |
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, rlonu(iip1),xprimu(iip1),rlonp025(iip1),xprimp025(iip1) |
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c .... variables locales .... |
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c |
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REAL dzoom |
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DOUBLE PRECISION xlon(iip1),xprimm(iip1),xuv |
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DOUBLE PRECISION xtild(0:nmax2) |
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DOUBLE PRECISION fhyp(0:nmax2),ffdx,beta,Xprimt(0:nmax2) |
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DOUBLE PRECISION Xf(0:nmax2),xxpr(0:nmax2) |
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DOUBLE PRECISION xvrai(iip1),xxprim(iip1) |
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DOUBLE PRECISION pi,depi,epsilon,xzoom,fa,fb |
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DOUBLE PRECISION Xf1, Xfi , a0,a1,a2,a3,xi2 |
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INTEGER i,it,ik,iter,ii,idif,ii1,ii2 |
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DOUBLE PRECISION xi,xo1,xmoy,xlon2,fxm,Xprimin |
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DOUBLE PRECISION champmin,champmax,decalx |
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INTEGER is2 |
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SAVE is2 |
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DOUBLE PRECISION heavyside |
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pi = 2. * ASIN(1.) |
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depi = 2. * pi |
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epsilon = 1.e-3 |
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xzoom = xzoomdeg * pi/180. |
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c |
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decalx = .75 |
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IF( grossism.EQ.1..AND.scal180 ) THEN |
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decalx = 1. |
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ENDIF |
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WRITE(6,*) 'FXHYP scal180,decalx', scal180,decalx |
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c |
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IF( dzooma.LT.1.) THEN |
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dzoom = dzooma * depi |
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ELSEIF( dzooma.LT. 25. ) THEN |
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WRITE(6,*) ' Le param. dzoomx pour fxhyp est trop petit ! L aug |
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,menter et relancer ! ' |
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STOP 1 |
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ELSE |
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dzoom = dzooma * pi/180. |
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ENDIF |
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WRITE(6,*) ' xzoom( rad.),grossism,tau,dzoom (radians)' |
SUBROUTINE fxhyp(xprimm025, rlonv, xprimv, rlonu, xprimu, xprimp025) |
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WRITE(6,24) xzoom,grossism,tau,dzoom |
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DO i = 0, nmax2 |
! From LMDZ4/libf/dyn3d/fxhyp.F, version 1.2, 2005/06/03 09:11:32 |
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xtild(i) = - pi + FLOAT(i) * depi /nmax2 |
! Author: P. Le Van, from formulas by R. Sadourny |
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ENDDO |
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! Calcule les longitudes et dérivées dans la grille du GCM pour |
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DO i = nmax, nmax2 |
! une fonction f(x) à dérivée tangente hyperbolique. |
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fa = tau* ( dzoom/2. - xtild(i) ) |
! On doit avoir grossismx \times dzoomx < pi (radians) |
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fb = xtild(i) * ( pi - xtild(i) ) |
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USE dimens_m, ONLY: iim |
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IF( 200.* fb .LT. - fa ) THEN |
use nr_util, only: pi_d, twopi_d |
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fhyp ( i) = - 1. |
use serre, only: clon, grossismx, dzoomx, taux |
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ELSEIF( 200. * fb .LT. fa ) THEN |
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fhyp ( i) = 1. |
REAL, intent(out):: xprimm025(:), rlonv(:), xprimv(:) ! (iim + 1) |
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ELSE |
real, intent(out):: rlonu(:), xprimu(:), xprimp025(:) ! (iim + 1) |
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IF( ABS(fa).LT.1.e-13.AND.ABS(fb).LT.1.e-13) THEN |
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IF( 200.*fb + fa.LT.1.e-10 ) THEN |
! Local: |
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fhyp ( i ) = - 1. |
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ELSEIF( 200.*fb - fa.LT.1.e-10 ) THEN |
DOUBLE PRECISION champmin, champmax |
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fhyp ( i ) = 1. |
real rlonm025(iim + 1), rlonp025(iim + 1) |
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ENDIF |
INTEGER, PARAMETER:: nmax = 30000, nmax2 = 2*nmax |
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ELSE |
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fhyp ( i ) = TANH ( fa/fb ) |
LOGICAL, PARAMETER:: scal180 = .TRUE. |
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ENDIF |
! scal180 = .TRUE. si on veut avoir le premier point scalaire pour |
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ENDIF |
! une grille reguliere (grossismx = 1., taux=0., clon=0.) a |
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IF ( xtild(i).EQ. 0. ) fhyp(i) = 1. |
! -180. degres. sinon scal180 = .FALSE. |
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IF ( xtild(i).EQ. pi ) fhyp(i) = -1. |
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REAL dzoom |
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ENDDO |
DOUBLE PRECISION xlon(iim + 1), xprimm(iim + 1), xuv |
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DOUBLE PRECISION xtild(0:nmax2) |
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cc .... Calcul de beta .... |
DOUBLE PRECISION fhyp(0:nmax2), ffdx, beta, Xprimt(0:nmax2) |
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DOUBLE PRECISION Xf(0:nmax2), xxpr(0:nmax2) |
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ffdx = 0. |
DOUBLE PRECISION xvrai(iim + 1), xxprim(iim + 1) |
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DOUBLE PRECISION my_eps, xzoom, fa, fb |
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DO i = nmax +1,nmax2 |
DOUBLE PRECISION Xf1, Xfi, a0, a1, a2, a3, xi2 |
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INTEGER i, it, ik, iter, ii, idif, ii1, ii2 |
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xmoy = 0.5 * ( xtild(i-1) + xtild( i ) ) |
DOUBLE PRECISION xi, xo1, xmoy, xlon2, fxm, Xprimin |
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fa = tau* ( dzoom/2. - xmoy ) |
DOUBLE PRECISION decalx |
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fb = xmoy * ( pi - xmoy ) |
INTEGER, save:: is2 |
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IF( 200.* fb .LT. - fa ) THEN |
!---------------------------------------------------------------------- |
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fxm = - 1. |
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ELSEIF( 200. * fb .LT. fa ) THEN |
my_eps = 1e-3 |
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fxm = 1. |
xzoom = clon * pi_d / 180. |
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IF (grossismx == 1. .AND. scal180) THEN |
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decalx = 1. |
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else |
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decalx = 0.75 |
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END IF |
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IF (dzoomx < 1.) THEN |
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dzoom = dzoomx * twopi_d |
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ELSE IF (dzoomx < 25.) THEN |
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print *, "Le paramètre dzoomx pour fxhyp est trop petit. " & |
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// "L'augmenter et relancer." |
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STOP 1 |
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ELSE |
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dzoom = dzoomx * pi_d / 180. |
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END IF |
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print *, 'dzoom (rad):', dzoom |
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DO i = 0, nmax2 |
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xtild(i) = - pi_d + REAL(i) * twopi_d / nmax2 |
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END DO |
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DO i = nmax, nmax2 |
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fa = taux* (dzoom / 2. - xtild(i)) |
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fb = xtild(i) * (pi_d - xtild(i)) |
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IF (200.* fb < - fa) THEN |
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fhyp(i) = - 1. |
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ELSE IF (200. * fb < fa) THEN |
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fhyp(i) = 1. |
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ELSE |
ELSE |
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IF( ABS(fa).LT.1.e-13.AND.ABS(fb).LT.1.e-13) THEN |
IF (ABS(fa) < 1e-13.AND.ABS(fb) < 1e-13) THEN |
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IF( 200.*fb + fa.LT.1.e-10 ) THEN |
IF (200.*fb + fa < 1e-10) THEN |
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fxm = - 1. |
fhyp(i) = - 1. |
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ELSEIF( 200.*fb - fa.LT.1.e-10 ) THEN |
ELSE IF (200.*fb - fa < 1e-10) THEN |
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fxm = 1. |
fhyp(i) = 1. |
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ENDIF |
END IF |
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ELSE |
ELSE |
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fxm = TANH ( fa/fb ) |
fhyp(i) = TANH(fa / fb) |
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ENDIF |
END IF |
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ENDIF |
END IF |
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IF ( xmoy.EQ. 0. ) fxm = 1. |
IF (xtild(i) == 0.) fhyp(i) = 1. |
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IF ( xmoy.EQ. pi ) fxm = -1. |
IF (xtild(i) == pi_d) fhyp(i) = -1. |
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END DO |
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ffdx = ffdx + fxm * ( xtild(i) - xtild(i-1) ) |
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! Calcul de beta |
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ENDDO |
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ffdx = 0. |
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beta = ( grossism * ffdx - pi ) / ( ffdx - pi ) |
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DO i = nmax + 1, nmax2 |
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IF( 2.*beta - grossism.LE. 0.) THEN |
xmoy = 0.5 * (xtild(i-1) + xtild(i)) |
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WRITE(6,*) ' ** Attention ! La valeur beta calculee dans la rou |
fa = taux* (dzoom / 2. - xmoy) |
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,tine fxhyp est mauvaise ! ' |
fb = xmoy * (pi_d - xmoy) |
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WRITE(6,*)'Modifier les valeurs de grossismx ,tau ou dzoomx ', |
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, ' et relancer ! *** ' |
IF (200.* fb < - fa) THEN |
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STOP 1 |
fxm = - 1. |
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ENDIF |
ELSE IF (200. * fb < fa) THEN |
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fxm = 1. |
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c ..... calcul de Xprimt ..... |
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c |
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DO i = nmax, nmax2 |
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Xprimt(i) = beta + ( grossism - beta ) * fhyp(i) |
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ENDDO |
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c |
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DO i = nmax+1, nmax2 |
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Xprimt( nmax2 - i ) = Xprimt( i ) |
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ENDDO |
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c |
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c ..... Calcul de Xf ........ |
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Xf(0) = - pi |
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DO i = nmax +1, nmax2 |
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xmoy = 0.5 * ( xtild(i-1) + xtild( i ) ) |
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fa = tau* ( dzoom/2. - xmoy ) |
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fb = xmoy * ( pi - xmoy ) |
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IF( 200.* fb .LT. - fa ) THEN |
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fxm = - 1. |
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ELSEIF( 200. * fb .LT. fa ) THEN |
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fxm = 1. |
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ELSE |
ELSE |
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fxm = TANH ( fa/fb ) |
IF (ABS(fa) < 1e-13.AND.ABS(fb) < 1e-13) THEN |
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ENDIF |
IF (200.*fb + fa < 1e-10) THEN |
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fxm = - 1. |
116 |
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ELSE IF (200.*fb - fa < 1e-10) THEN |
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fxm = 1. |
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END IF |
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ELSE |
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fxm = TANH(fa / fb) |
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END IF |
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END IF |
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IF (xmoy == 0.) fxm = 1. |
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IF (xmoy == pi_d) fxm = -1. |
126 |
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127 |
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ffdx = ffdx + fxm * (xtild(i) - xtild(i-1)) |
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END DO |
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beta = (grossismx * ffdx - pi_d) / (ffdx - pi_d) |
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IF (2. * beta - grossismx <= 0.) THEN |
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print *, 'Attention ! La valeur beta calculée dans fxhyp est mauvaise.' |
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print *, 'Modifier les valeurs de grossismx, taux ou dzoomx et relancer.' |
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STOP 1 |
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END IF |
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! calcul de Xprimt |
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DO i = nmax, nmax2 |
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Xprimt(i) = beta + (grossismx - beta) * fhyp(i) |
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END DO |
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DO i = nmax + 1, nmax2 |
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Xprimt(nmax2 - i) = Xprimt(i) |
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END DO |
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! Calcul de Xf |
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Xf(0) = - pi_d |
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DO i = nmax + 1, nmax2 |
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xmoy = 0.5 * (xtild(i-1) + xtild(i)) |
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fa = taux* (dzoom / 2. - xmoy) |
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fb = xmoy * (pi_d - xmoy) |
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IF (200.* fb < - fa) THEN |
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fxm = - 1. |
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ELSE IF (200. * fb < fa) THEN |
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fxm = 1. |
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ELSE |
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fxm = TANH(fa / fb) |
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END IF |
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IF (xmoy == 0.) fxm = 1. |
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IF (xmoy == pi_d) fxm = -1. |
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xxpr(i) = beta + (grossismx - beta) * fxm |
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END DO |
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DO i = nmax + 1, nmax2 |
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xxpr(nmax2-i + 1) = xxpr(i) |
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END DO |
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DO i=1, nmax2 |
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Xf(i) = Xf(i-1) + xxpr(i) * (xtild(i) - xtild(i-1)) |
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END DO |
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! xuv = 0. si calcul aux points scalaires |
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! xuv = 0.5 si calcul aux points U |
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loop_ik: DO ik = 1, 4 |
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IF (ik == 1) THEN |
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xuv = -0.25 |
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ELSE IF (ik == 2) THEN |
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xuv = 0. |
186 |
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ELSE IF (ik == 3) THEN |
187 |
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xuv = 0.50 |
188 |
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ELSE IF (ik == 4) THEN |
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xuv = 0.25 |
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END IF |
191 |
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xo1 = 0. |
193 |
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ii1=1 |
195 |
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ii2=iim |
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IF (ik == 1.and.grossismx == 1.) THEN |
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ii1 = 2 |
198 |
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ii2 = iim + 1 |
199 |
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END IF |
200 |
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DO i = ii1, ii2 |
202 |
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xlon2 = - pi_d + (REAL(i) + xuv - decalx) * twopi_d / REAL(iim) |
203 |
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Xfi = xlon2 |
204 |
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205 |
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it = nmax2 |
206 |
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do while (xfi < xf(it) .and. it >= 1) |
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it = it - 1 |
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end do |
209 |
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! Calcul de Xf(xi) |
211 |
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xi = xtild(it) |
213 |
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214 |
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IF (it == nmax2) THEN |
215 |
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it = nmax2 -1 |
216 |
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Xf(it + 1) = pi_d |
217 |
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END IF |
218 |
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219 |
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! Appel de la routine qui calcule les coefficients a0, a1, |
220 |
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! a2, a3 d'un polynome de degre 3 qui passe par les points |
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! (Xf(it), xtild(it)) et (Xf(it + 1), xtild(it + 1)) |
222 |
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223 |
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CALL coefpoly(Xf(it), Xf(it + 1), Xprimt(it), Xprimt(it + 1), & |
224 |
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xtild(it), xtild(it + 1), a0, a1, a2, a3) |
225 |
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226 |
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Xf1 = Xf(it) |
227 |
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Xprimin = a1 + 2.* a2 * xi + 3.*a3 * xi *xi |
228 |
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229 |
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iter = 1 |
230 |
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231 |
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do |
232 |
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xi = xi - (Xf1 - Xfi) / Xprimin |
233 |
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IF (ABS(xi - xo1) <= my_eps .or. iter == 300) exit |
234 |
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xo1 = xi |
235 |
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xi2 = xi * xi |
236 |
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Xf1 = a0 + a1 * xi + a2 * xi2 + a3 * xi2 * xi |
237 |
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Xprimin = a1 + 2.* a2 * xi + 3.* a3 * xi2 |
238 |
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end DO |
239 |
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240 |
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if (ABS(xi - xo1) > my_eps) then |
241 |
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! iter == 300 |
242 |
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print *, 'Pas de solution.' |
243 |
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print *, i, xlon2 |
244 |
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STOP 1 |
245 |
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end if |
246 |
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247 |
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xxprim(i) = twopi_d / (REAL(iim) * Xprimin) |
248 |
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xvrai(i) = xi + xzoom |
249 |
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end DO |
250 |
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251 |
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IF (ik == 1 .and. grossismx == 1.) THEN |
252 |
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xvrai(1) = xvrai(iim + 1)-twopi_d |
253 |
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xxprim(1) = xxprim(iim + 1) |
254 |
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END IF |
255 |
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256 |
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DO i = 1, iim |
257 |
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xlon(i) = xvrai(i) |
258 |
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xprimm(i) = xxprim(i) |
259 |
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END DO |
260 |
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IF ( xmoy.EQ. 0. ) fxm = 1. |
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IF ( xmoy.EQ. pi ) fxm = -1. |
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xxpr(i) = beta + ( grossism - beta ) * fxm |
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ENDDO |
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DO i = nmax+1, nmax2 |
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xxpr(nmax2-i+1) = xxpr(i) |
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ENDDO |
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DO i=1,nmax2 |
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Xf(i) = Xf(i-1) + xxpr(i) * ( xtild(i) - xtild(i-1) ) |
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ENDDO |
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c ***************************************************************** |
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c |
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c ..... xuv = 0. si calcul aux pts scalaires ........ |
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c ..... xuv = 0.5 si calcul aux pts U ........ |
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c |
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WRITE(6,18) |
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c |
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DO 5000 ik = 1, 4 |
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IF( ik.EQ.1 ) THEN |
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xuv = -0.25 |
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ELSE IF ( ik.EQ.2 ) THEN |
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xuv = 0. |
|
|
ELSE IF ( ik.EQ.3 ) THEN |
|
|
xuv = 0.50 |
|
|
ELSE IF ( ik.EQ.4 ) THEN |
|
|
xuv = 0.25 |
|
|
ENDIF |
|
|
|
|
|
xo1 = 0. |
|
|
|
|
|
ii1=1 |
|
|
ii2=iim |
|
|
IF(ik.EQ.1.and.grossism.EQ.1.) THEN |
|
|
ii1 = 2 |
|
|
ii2 = iim+1 |
|
|
ENDIF |
|
|
DO 1500 i = ii1, ii2 |
|
|
|
|
|
xlon2 = - pi + (FLOAT(i) + xuv - decalx) * depi / FLOAT(iim) |
|
|
|
|
|
Xfi = xlon2 |
|
|
c |
|
|
DO 250 it = nmax2,0,-1 |
|
|
IF( Xfi.GE.Xf(it)) GO TO 350 |
|
|
250 CONTINUE |
|
|
|
|
|
it = 0 |
|
|
|
|
|
350 CONTINUE |
|
|
|
|
|
c ...... Calcul de Xf(xi) ...... |
|
|
c |
|
|
xi = xtild(it) |
|
|
|
|
|
IF(it.EQ.nmax2) THEN |
|
|
it = nmax2 -1 |
|
|
Xf(it+1) = pi |
|
|
ENDIF |
|
|
c ..................................................................... |
|
|
c |
|
|
c Appel de la routine qui calcule les coefficients a0,a1,a2,a3 d'un |
|
|
c polynome de degre 3 qui passe par les points (Xf(it),xtild(it) ) |
|
|
c et (Xf(it+1),xtild(it+1) ) |
|
|
|
|
|
CALL coefpoly ( Xf(it),Xf(it+1),Xprimt(it),Xprimt(it+1), |
|
|
, xtild(it),xtild(it+1), a0, a1, a2, a3 ) |
|
|
|
|
|
Xf1 = Xf(it) |
|
|
Xprimin = a1 + 2.* a2 * xi + 3.*a3 * xi *xi |
|
|
|
|
|
DO 500 iter = 1,300 |
|
|
xi = xi - ( Xf1 - Xfi )/ Xprimin |
|
|
|
|
|
IF( ABS(xi-xo1).LE.epsilon) GO TO 550 |
|
|
xo1 = xi |
|
|
xi2 = xi * xi |
|
|
Xf1 = a0 + a1 * xi + a2 * xi2 + a3 * xi2 * xi |
|
|
Xprimin = a1 + 2.* a2 * xi + 3.* a3 * xi2 |
|
|
500 CONTINUE |
|
|
WRITE(6,*) ' Pas de solution ***** ',i,xlon2,iter |
|
|
STOP 6 |
|
|
550 CONTINUE |
|
|
|
|
|
xxprim(i) = depi/ ( FLOAT(iim) * Xprimin ) |
|
|
xvrai(i) = xi + xzoom |
|
|
|
|
|
1500 CONTINUE |
|
|
|
|
|
|
|
|
IF(ik.EQ.1.and.grossism.EQ.1.) THEN |
|
|
xvrai(1) = xvrai(iip1)-depi |
|
|
xxprim(1) = xxprim(iip1) |
|
|
ENDIF |
|
|
DO i = 1 , iim |
|
|
xlon(i) = xvrai(i) |
|
|
xprimm(i) = xxprim(i) |
|
|
ENDDO |
|
261 |
DO i = 1, iim -1 |
DO i = 1, iim -1 |
262 |
IF( xvrai(i+1). LT. xvrai(i) ) THEN |
IF (xvrai(i + 1) < xvrai(i)) THEN |
263 |
WRITE(6,*) ' PBS. avec rlonu(',i+1,') plus petit que rlonu(',i, |
print *, 'Problème avec rlonu(', i + 1, & |
264 |
, ')' |
') plus petit que rlonu(', i, ')' |
265 |
STOP 7 |
STOP 1 |
266 |
ENDIF |
END IF |
267 |
ENDDO |
END DO |
|
c |
|
|
c ... Reorganisation des longitudes pour les avoir entre - pi et pi .. |
|
|
c ........................................................................ |
|
268 |
|
|
269 |
champmin = 1.e12 |
! Réorganisation des longitudes pour les avoir entre - pi et pi |
270 |
champmax = -1.e12 |
|
271 |
|
champmin = 1e12 |
272 |
|
champmax = -1e12 |
273 |
DO i = 1, iim |
DO i = 1, iim |
274 |
champmin = MIN( champmin,xvrai(i) ) |
champmin = MIN(champmin, xvrai(i)) |
275 |
champmax = MAX( champmax,xvrai(i) ) |
champmax = MAX(champmax, xvrai(i)) |
276 |
ENDDO |
END DO |
277 |
|
|
278 |
IF(champmin .GE.-pi-0.10.and.champmax.LE.pi+0.10 ) THEN |
IF (.not. (champmin >= -pi_d - 0.1 .and. champmax <= pi_d + 0.1)) THEN |
279 |
GO TO 1600 |
print *, 'Reorganisation des longitudes pour avoir entre - pi', & |
280 |
ELSE |
' et pi ' |
281 |
WRITE(6,*) 'Reorganisation des longitudes pour avoir entre - pi', |
|
282 |
, ' et pi ' |
IF (xzoom <= 0.) THEN |
283 |
c |
IF (ik == 1) THEN |
284 |
IF( xzoom.LE.0.) THEN |
i = 1 |
285 |
IF( ik.EQ. 1 ) THEN |
|
286 |
DO i = 1, iim |
do while (xvrai(i) < - pi_d .and. i < iim) |
287 |
IF( xvrai(i).GE. - pi ) GO TO 80 |
i = i + 1 |
288 |
ENDDO |
end do |
289 |
WRITE(6,*) ' PBS. 1 ! Xvrai plus petit que - pi ! ' |
|
290 |
STOP 8 |
if (xvrai(i) < - pi_d) then |
291 |
80 CONTINUE |
print *, 'Xvrai plus petit que - pi !' |
292 |
is2 = i |
STOP 1 |
293 |
ENDIF |
end if |
294 |
|
|
295 |
IF( is2.NE. 1 ) THEN |
is2 = i |
296 |
DO ii = is2 , iim |
END IF |
297 |
xlon (ii-is2+1) = xvrai(ii) |
|
298 |
xprimm(ii-is2+1) = xxprim(ii) |
IF (is2.NE. 1) THEN |
299 |
ENDDO |
DO ii = is2, iim |
300 |
DO ii = 1 , is2 -1 |
xlon(ii-is2 + 1) = xvrai(ii) |
301 |
xlon (ii+iim-is2+1) = xvrai(ii) + depi |
xprimm(ii-is2 + 1) = xxprim(ii) |
302 |
xprimm(ii+iim-is2+1) = xxprim(ii) |
END DO |
303 |
ENDDO |
DO ii = 1, is2 -1 |
304 |
ENDIF |
xlon(ii + iim-is2 + 1) = xvrai(ii) + twopi_d |
305 |
ELSE |
xprimm(ii + iim-is2 + 1) = xxprim(ii) |
306 |
IF( ik.EQ.1 ) THEN |
END DO |
307 |
DO i = iim,1,-1 |
END IF |
308 |
IF( xvrai(i).LE. pi ) GO TO 90 |
ELSE |
309 |
ENDDO |
IF (ik == 1) THEN |
310 |
WRITE(6,*) ' PBS. 2 ! Xvrai plus grand que pi ! ' |
i = iim |
311 |
STOP 9 |
|
312 |
90 CONTINUE |
do while (xvrai(i) > pi_d .and. i > 1) |
313 |
is2 = i |
i = i - 1 |
314 |
ENDIF |
end do |
315 |
idif = iim -is2 |
|
316 |
DO ii = 1, is2 |
if (xvrai(i) > pi_d) then |
317 |
xlon (ii+idif) = xvrai(ii) |
print *, 'Xvrai plus grand que pi !' |
318 |
xprimm(ii+idif) = xxprim(ii) |
STOP 1 |
319 |
ENDDO |
end if |
320 |
DO ii = 1, idif |
|
321 |
xlon (ii) = xvrai (ii+is2) - depi |
is2 = i |
322 |
xprimm(ii) = xxprim(ii+is2) |
END IF |
323 |
ENDDO |
|
324 |
ENDIF |
idif = iim -is2 |
325 |
ENDIF |
|
326 |
c |
DO ii = 1, is2 |
327 |
c ......... Fin de la reorganisation ............................ |
xlon(ii + idif) = xvrai(ii) |
328 |
|
xprimm(ii + idif) = xxprim(ii) |
329 |
1600 CONTINUE |
END DO |
330 |
|
|
331 |
|
DO ii = 1, idif |
332 |
xlon ( iip1) = xlon(1) + depi |
xlon(ii) = xvrai(ii + is2) - twopi_d |
333 |
xprimm( iip1 ) = xprimm (1 ) |
xprimm(ii) = xxprim(ii + is2) |
334 |
|
END DO |
335 |
DO i = 1, iim+1 |
END IF |
336 |
xvrai(i) = xlon(i)*180./pi |
END IF |
337 |
ENDDO |
|
338 |
|
! Fin de la reorganisation |
339 |
IF( ik.EQ.1 ) THEN |
|
340 |
c WRITE(6,*) ' XLON aux pts. V-0.25 apres ( en deg. ) ' |
xlon(iim + 1) = xlon(1) + twopi_d |
341 |
c WRITE(6,18) |
xprimm(iim + 1) = xprimm(1) |
342 |
c WRITE(6,68) xvrai |
|
343 |
c WRITE(6,*) ' XPRIM k ',ik |
DO i = 1, iim + 1 |
344 |
c WRITE(6,566) xprimm |
xvrai(i) = xlon(i)*180. / pi_d |
345 |
|
END DO |
346 |
DO i = 1,iim +1 |
|
347 |
rlonm025(i) = xlon( i ) |
IF (ik == 1) THEN |
348 |
xprimm025(i) = xprimm(i) |
DO i = 1, iim + 1 |
349 |
ENDDO |
rlonm025(i) = xlon(i) |
350 |
ELSE IF( ik.EQ.2 ) THEN |
xprimm025(i) = xprimm(i) |
351 |
c WRITE(6,18) |
END DO |
352 |
c WRITE(6,*) ' XLON aux pts. V apres ( en deg. ) ' |
ELSE IF (ik == 2) THEN |
353 |
c WRITE(6,68) xvrai |
rlonv = xlon |
354 |
c WRITE(6,*) ' XPRIM k ',ik |
xprimv = xprimm |
355 |
c WRITE(6,566) xprimm |
ELSE IF (ik == 3) THEN |
356 |
|
DO i = 1, iim + 1 |
357 |
DO i = 1,iim + 1 |
rlonu(i) = xlon(i) |
358 |
rlonv(i) = xlon( i ) |
xprimu(i) = xprimm(i) |
359 |
xprimv(i) = xprimm(i) |
END DO |
360 |
ENDDO |
ELSE IF (ik == 4) THEN |
361 |
|
DO i = 1, iim + 1 |
362 |
ELSE IF( ik.EQ.3) THEN |
rlonp025(i) = xlon(i) |
363 |
c WRITE(6,18) |
xprimp025(i) = xprimm(i) |
364 |
c WRITE(6,*) ' XLON aux pts. U apres ( en deg. ) ' |
END DO |
365 |
c WRITE(6,68) xvrai |
END IF |
366 |
c WRITE(6,*) ' XPRIM ik ',ik |
end DO loop_ik |
367 |
c WRITE(6,566) xprimm |
|
368 |
|
print * |
369 |
DO i = 1,iim + 1 |
|
370 |
rlonu(i) = xlon( i ) |
DO i = 1, iim |
371 |
xprimu(i) = xprimm(i) |
xlon(i) = rlonv(i + 1) - rlonv(i) |
372 |
ENDDO |
END DO |
373 |
|
champmin = 1e12 |
374 |
ELSE IF( ik.EQ.4 ) THEN |
champmax = -1e12 |
375 |
c WRITE(6,18) |
DO i = 1, iim |
376 |
c WRITE(6,*) ' XLON aux pts. V+0.25 apres ( en deg. ) ' |
champmin = MIN(champmin, xlon(i)) |
377 |
c WRITE(6,68) xvrai |
champmax = MAX(champmax, xlon(i)) |
378 |
c WRITE(6,*) ' XPRIM ik ',ik |
END DO |
379 |
c WRITE(6,566) xprimm |
champmin = champmin * 180. / pi_d |
380 |
|
champmax = champmax * 180. / pi_d |
381 |
DO i = 1,iim + 1 |
|
382 |
rlonp025(i) = xlon( i ) |
DO i = 1, iim + 1 |
383 |
xprimp025(i) = xprimm(i) |
IF (rlonp025(i) < rlonv(i)) THEN |
384 |
ENDDO |
print *, ' Attention ! rlonp025 < rlonv', i |
385 |
|
STOP 1 |
386 |
ENDIF |
END IF |
387 |
|
|
388 |
5000 CONTINUE |
IF (rlonv(i) < rlonm025(i)) THEN |
389 |
c |
print *, ' Attention ! rlonm025 > rlonv', i |
390 |
WRITE(6,18) |
STOP 1 |
391 |
c |
END IF |
392 |
c ........... fin de la boucle do 5000 ............ |
|
393 |
|
IF (rlonp025(i) > rlonu(i)) THEN |
394 |
DO i = 1, iim |
print *, ' Attention ! rlonp025 > rlonu', i |
395 |
xlon(i) = rlonv(i+1) - rlonv(i) |
STOP 1 |
396 |
ENDDO |
END IF |
397 |
champmin = 1.e12 |
END DO |
398 |
champmax = -1.e12 |
|
399 |
DO i = 1, iim |
print *, ' Longitudes ' |
400 |
champmin = MIN( champmin, xlon(i) ) |
print 3, champmin, champmax |
401 |
champmax = MAX( champmax, xlon(i) ) |
|
402 |
ENDDO |
3 Format(1x, ' Au centre du zoom, la longueur de la maille est', & |
403 |
champmin = champmin * 180./pi |
' d environ ', f0.2, ' degres ', /, & |
404 |
champmax = champmax * 180./pi |
' alors que la maille en dehors de la zone du zoom est ', & |
405 |
|
"d'environ", f0.2, ' degres ') |
406 |
18 FORMAT(/) |
|
407 |
24 FORMAT(2x,'Parametres xzoom,gross,tau ,dzoom pour fxhyp ',4f8.3) |
END SUBROUTINE fxhyp |
|
68 FORMAT(1x,7f9.2) |
|
|
566 FORMAT(1x,7f9.4) |
|
408 |
|
|
409 |
RETURN |
end module fxhyp_m |
|
END |
|