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SUBROUTINE gwprofil(nlon,nlev,kgwd,kdx,ktest,kkcrith,kcrit,paphm1,prho, & |
module gwprofil_m |
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pstab,pvph,pri,ptau,pdmod,psig,pvar) |
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!**** *GWPROFIL* |
IMPLICIT NONE |
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! PURPOSE. |
contains |
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! -------- |
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!** INTERFACE. |
SUBROUTINE gwprofil(nlon, nlev, kgwd, kdx, ktest, kkcrith, kcrit, paphm1, & |
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! ---------- |
prho, pstab, pvph, pri, ptau, pdmod, psig, pvar) |
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! FROM *GWDRAG* |
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! EXPLICIT ARGUMENTS : |
! Method. The stress profile for gravity waves is computed as |
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! -------------------- |
! follows: it is constant (no gwd) at the levels between the |
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! ==== INPUTS === |
! ground and the top of the blocked layer (kkenvh). It decreases |
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! ==== OUTPUTS === |
! linearly with height from the top of the blocked layer to |
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! 3*varor (kknu), to simulate lee waves or nonlinear gravity wave |
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! breaking. Above it is constant, except when the wave encounters |
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! a critical level (kcrit) or when it breaks. |
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! IMPLICIT ARGUMENTS : NONE |
! Reference. |
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! -------------------- |
! See ECMWF research department documentation of the "I.F.S." |
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! METHOD: |
! Modifications. |
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! ------- |
! Passage of the new gwdrag TO I.F.S. (F. LOTT, 22/11/93) |
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! THE STRESS PROFILE FOR GRAVITY WAVES IS COMPUTED AS FOLLOWS: |
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! IT IS CONSTANT (NO GWD) AT THE LEVELS BETWEEN THE GROUND |
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! AND THE TOP OF THE BLOCKED LAYER (KKENVH). |
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! IT DECREASES LINEARLY WITH HEIGHTS FROM THE TOP OF THE |
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! BLOCKED LAYER TO 3*VAROR (kKNU), TO SIMULATES LEE WAVES OR |
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! NONLINEAR GRAVITY WAVE BREAKING. |
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! ABOVE IT IS CONSTANT, EXCEPT WHEN THE WAVE ENCOUNTERS A CRITICAL |
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! LEVEL (KCRIT) OR WHEN IT BREAKS. |
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USE dimphy, ONLY : klev, klon |
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USE yoegwd, ONLY : gkdrag, grahilo, grcrit, gssec, gtsec, nstra |
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! 0.1 ARGUMENTS |
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! EXTERNALS. |
INTEGER nlon, nlev |
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! ---------- |
INTEGER kkcrith(nlon), kcrit(nlon), kdx(nlon), ktest(nlon) |
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REAL paphm1(nlon, nlev+1), pstab(nlon, nlev+1), prho(nlon, nlev+1), & |
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pvph(nlon, nlev+1), pri(nlon, nlev+1), ptau(nlon, nlev+1) |
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! REFERENCE. |
REAL pdmod(nlon) |
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! ---------- |
REAL, INTENT (IN) :: psig(nlon) |
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REAL, INTENT (IN) :: pvar(nlon) |
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! SEE ECMWF RESEARCH DEPARTMENT DOCUMENTATION OF THE "I.F.S." |
! 0.2 LOCAL ARRAYS |
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! AUTHOR. |
INTEGER ilevh, ji, kgwd, jl, jk |
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! ------- |
REAL zsqr, zalfa, zriw, zdel, zb, zalpha, zdz2n |
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REAL zdelp, zdelpt |
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REAL zdz2(klon, klev), znorm(klon), zoro(klon) |
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REAL ztau(klon, klev+1) |
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! MODIFICATIONS. |
!----------------------------------------------------------------------- |
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! -------------- |
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! PASSAGE OF THE NEW GWDRAG TO I.F.S. (F. LOTT, 22/11/93) |
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!----------------------------------------------------------------------- |
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USE dimens_m |
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USE dimphy |
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USE suphec_m |
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USE yoegwd |
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IMPLICIT NONE |
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! 1. INITIALIZATION |
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! COMPUTATIONAL CONSTANTS. |
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ilevh = klev/3 |
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DO jl = 1, klon |
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IF (ktest(jl)==1) THEN |
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zoro(jl) = psig(jl)*pdmod(jl)/4./max(pvar(jl), 1.0) |
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ztau(jl, klev+1) = ptau(jl, klev+1) |
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END IF |
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end DO |
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!----------------------------------------------------------------------- |
DO jk = klev, 2, -1 |
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! 4.1 CONSTANT WAVE STRESS UNTIL TOP OF THE |
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!* 0.1 ARGUMENTS |
! BLOCKING LAYER. |
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! --------- |
DO jl = 1, klon |
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INTEGER nlon, nlev |
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INTEGER kkcrith(nlon), kcrit(nlon), kdx(nlon), ktest(nlon) |
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REAL paphm1(nlon,nlev+1), pstab(nlon,nlev+1), prho(nlon,nlev+1), & |
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pvph(nlon,nlev+1), pri(nlon,nlev+1), ptau(nlon,nlev+1) |
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REAL pdmod(nlon) |
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REAL, INTENT (IN) :: psig(nlon) |
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REAL, INTENT (IN) :: pvar(nlon) |
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!----------------------------------------------------------------------- |
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!* 0.2 LOCAL ARRAYS |
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! ------------ |
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INTEGER ilevh, ji, kgwd, jl, jk |
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REAL zsqr, zalfa, zriw, zdel, zb, zalpha, zdz2n |
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REAL zdelp, zdelpt |
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REAL zdz2(klon,klev), znorm(klon), zoro(klon) |
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REAL ztau(klon,klev+1) |
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!----------------------------------------------------------------------- |
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!* 1. INITIALIZATION |
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! -------------- |
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! print *,' entree gwprofil' |
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100 CONTINUE |
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!* COMPUTATIONAL CONSTANTS. |
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! ------------- ---------- |
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ilevh = klev/3 |
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! DO 400 ji=1,kgwd |
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! jl=kdx(ji) |
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! Modif vectorisation 02/04/2004 |
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DO 400 jl = 1, klon |
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IF (ktest(jl)==1) THEN |
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zoro(jl) = psig(jl)*pdmod(jl)/4./max(pvar(jl),1.0) |
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ztau(jl,klev+1) = ptau(jl,klev+1) |
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END IF |
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400 CONTINUE |
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DO 430 jk = klev, 2, -1 |
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!* 4.1 CONSTANT WAVE STRESS UNTIL TOP OF THE |
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! BLOCKING LAYER. |
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410 CONTINUE |
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! DO 411 ji=1,kgwd |
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! jl=kdx(ji) |
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! Modif vectorisation 02/04/2004 |
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DO 411 jl = 1, klon |
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IF (ktest(jl)==1) THEN |
IF (ktest(jl)==1) THEN |
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IF (jk>kkcrith(jl)) THEN |
IF (jk>kkcrith(jl)) THEN |
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ptau(jl,jk) = ztau(jl,klev+1) |
ptau(jl, jk) = ztau(jl, klev+1) |
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! ENDIF |
ELSE |
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! IF(JK.EQ.KKCRITH(JL)) THEN |
ptau(jl, jk) = grahilo*ztau(jl, klev+1) |
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ELSE |
END IF |
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ptau(jl,jk) = grahilo*ztau(jl,klev+1) |
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END IF |
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END IF |
END IF |
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411 CONTINUE |
end DO |
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!* 4.15 CONSTANT SHEAR STRESS UNTIL THE TOP OF THE |
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! LOW LEVEL FLOW LAYER. |
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415 CONTINUE |
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!* 4.2 WAVE DISPLACEMENT AT NEXT LEVEL. |
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420 CONTINUE |
! 4.2 WAVE DISPLACEMENT AT NEXT LEVEL. |
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DO jl = 1, klon |
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! DO 421 ji=1,kgwd |
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! jl=kdx(ji) |
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! Modif vectorisation 02/04/2004 |
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DO 421 jl = 1, klon |
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IF (ktest(jl)==1) THEN |
IF (ktest(jl)==1) THEN |
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IF (jk<kkcrith(jl)) THEN |
IF (jk<kkcrith(jl)) THEN |
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znorm(jl) = gkdrag*prho(jl,jk)*sqrt(pstab(jl,jk))*pvph(jl,jk)* & |
znorm(jl) = gkdrag * prho(jl, jk) * sqrt(pstab(jl, jk)) & |
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zoro(jl) |
* pvph(jl, jk)* zoro(jl) |
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zdz2(jl,jk) = ptau(jl,jk+1)/max(znorm(jl),gssec) |
zdz2(jl, jk) = ptau(jl, jk+1)/max(znorm(jl), gssec) |
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END IF |
END IF |
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END IF |
END IF |
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421 CONTINUE |
end DO |
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!* 4.3 WAVE RICHARDSON NUMBER, NEW WAVE DISPLACEMENT |
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!* AND STRESS: BREAKING EVALUATION AND CRITICAL |
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! LEVEL |
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! DO 431 ji=1,kgwd |
! 4.3 WAVE RICHARDSON NUMBER, NEW WAVE DISPLACEMENT |
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! jl=Kdx(ji) |
! AND STRESS: BREAKING EVALUATION AND CRITICAL |
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! Modif vectorisation 02/04/2004 |
! LEVEL |
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DO 431 jl = 1, klon |
DO jl = 1, klon |
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IF (ktest(jl)==1) THEN |
IF (ktest(jl)==1) THEN |
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IF (jk<kkcrith(jl)) THEN |
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IF (jk<kkcrith(jl)) THEN |
IF ((ptau(jl, jk+1)<gtsec) .OR. (jk<=kcrit(jl))) THEN |
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IF ((ptau(jl,jk+1)<gtsec) .OR. (jk<=kcrit(jl))) THEN |
ptau(jl, jk) = 0.0 |
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ptau(jl,jk) = 0.0 |
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ELSE |
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zsqr = sqrt(pri(jl,jk)) |
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zalfa = sqrt(pstab(jl,jk)*zdz2(jl,jk))/pvph(jl,jk) |
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zriw = pri(jl,jk)*(1.-zalfa)/(1+zalfa*zsqr)**2 |
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IF (zriw<grcrit) THEN |
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zdel = 4./zsqr/grcrit + 1./grcrit**2 + 4./grcrit |
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zb = 1./grcrit + 2./zsqr |
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zalpha = 0.5*(-zb+sqrt(zdel)) |
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zdz2n = (pvph(jl,jk)*zalpha)**2/pstab(jl,jk) |
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ptau(jl,jk) = znorm(jl)*zdz2n |
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ELSE |
ELSE |
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ptau(jl,jk) = znorm(jl)*zdz2(jl,jk) |
zsqr = sqrt(pri(jl, jk)) |
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zalfa = sqrt(pstab(jl, jk)*zdz2(jl, jk))/pvph(jl, jk) |
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zriw = pri(jl, jk)*(1.-zalfa)/(1+zalfa*zsqr)**2 |
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IF (zriw<grcrit) THEN |
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zdel = 4./zsqr/grcrit + 1./grcrit**2 + 4./grcrit |
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zb = 1./grcrit + 2./zsqr |
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zalpha = 0.5*(-zb+sqrt(zdel)) |
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zdz2n = (pvph(jl, jk)*zalpha)**2/pstab(jl, jk) |
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ptau(jl, jk) = znorm(jl)*zdz2n |
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ELSE |
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ptau(jl, jk) = znorm(jl)*zdz2(jl, jk) |
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END IF |
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ptau(jl, jk) = min(ptau(jl, jk), ptau(jl, jk+1)) |
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END IF |
END IF |
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ptau(jl,jk) = min(ptau(jl,jk),ptau(jl,jk+1)) |
END IF |
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END IF |
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END IF |
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END IF |
END IF |
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431 CONTINUE |
end DO |
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end DO |
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430 CONTINUE |
! REORGANISATION OF THE STRESS PROFILE AT LOW LEVEL |
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440 CONTINUE |
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! REORGANISATION OF THE STRESS PROFILE AT LOW LEVEL |
DO jl = 1, klon |
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IF (ktest(jl)==1) THEN |
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ztau(jl, kkcrith(jl)) = ptau(jl, kkcrith(jl)) |
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ztau(jl, nstra) = ptau(jl, nstra) |
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END IF |
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end DO |
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! DO 530 ji=1,kgwd |
DO jk = 1, klev |
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! jl=kdx(ji) |
DO jl = 1, klon |
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! Modif vectorisation 02/04/2004 |
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DO 530 jl = 1, klon |
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IF (ktest(jl)==1) THEN |
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ztau(jl,kkcrith(jl)) = ptau(jl,kkcrith(jl)) |
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ztau(jl,nstra) = ptau(jl,nstra) |
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END IF |
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530 CONTINUE |
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DO 531 jk = 1, klev |
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! DO 532 ji=1,kgwd |
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! jl=kdx(ji) |
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! Modif vectorisation 02/04/2004 |
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DO 532 jl = 1, klon |
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IF (ktest(jl)==1) THEN |
IF (ktest(jl)==1) THEN |
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IF (jk>kkcrith(jl)) THEN |
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zdelp = paphm1(jl, jk) - paphm1(jl, klev+1) |
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IF (jk>kkcrith(jl)) THEN |
zdelpt = paphm1(jl, kkcrith(jl)) - paphm1(jl, klev+1) |
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ptau(jl, jk) = ztau(jl, klev+1) & |
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zdelp = paphm1(jl,jk) - paphm1(jl,klev+1) |
+ (ztau(jl, kkcrith(jl)) - ztau(jl, klev+1))*zdelp/zdelpt |
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zdelpt = paphm1(jl,kkcrith(jl)) - paphm1(jl,klev+1) |
END IF |
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ptau(jl,jk) = ztau(jl,klev+1) + (ztau(jl,kkcrith(jl))-ztau(jl, & |
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klev+1))*zdelp/zdelpt |
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END IF |
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END IF |
END IF |
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532 CONTINUE |
end DO |
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! REORGANISATION IN THE STRATOSPHERE |
! REORGANISATION IN THE STRATOSPHERE |
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DO jl = 1, klon |
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! DO 533 ji=1,kgwd |
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! jl=kdx(ji) |
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! Modif vectorisation 02/04/2004 |
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DO 533 jl = 1, klon |
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IF (ktest(jl)==1) THEN |
IF (ktest(jl)==1) THEN |
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IF (jk < nstra) THEN |
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zdelp = paphm1(jl, nstra) |
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IF (jk<nstra) THEN |
zdelpt = paphm1(jl, jk) |
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ptau(jl, jk) = ztau(jl, nstra) * zdelpt / zdelp |
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zdelp = paphm1(jl,nstra) |
END IF |
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zdelpt = paphm1(jl,jk) |
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ptau(jl,jk) = ztau(jl,nstra)*zdelpt/zdelp |
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END IF |
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END IF |
END IF |
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533 CONTINUE |
end DO |
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! REORGANISATION IN THE TROPOSPHERE |
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! DO 534 ji=1,kgwd |
! REORGANISATION IN THE TROPOSPHERE |
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! jl=kdx(ji) |
DO jl = 1, klon |
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! Modif vectorisation 02/04/2004 |
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DO 534 jl = 1, klon |
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IF (ktest(jl)==1) THEN |
IF (ktest(jl)==1) THEN |
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IF (jk<kkcrith(jl) .AND. jk > nstra) THEN |
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zdelp = paphm1(jl, jk) - paphm1(jl, kkcrith(jl)) |
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IF (jk<kkcrith(jl) .AND. jk>nstra) THEN |
zdelpt = paphm1(jl, nstra) - paphm1(jl, kkcrith(jl)) |
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ptau(jl, jk) = ztau(jl, kkcrith(jl)) & |
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zdelp = paphm1(jl,jk) - paphm1(jl,kkcrith(jl)) |
+ (ztau(jl, nstra) - ztau(jl, kkcrith(jl)))*zdelp/zdelpt |
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zdelpt = paphm1(jl,nstra) - paphm1(jl,kkcrith(jl)) |
END IF |
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ptau(jl,jk) = ztau(jl,kkcrith(jl)) + (ztau(jl,nstra)-ztau(jl, & |
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kkcrith(jl)))*zdelp/zdelpt |
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END IF |
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END IF |
END IF |
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534 CONTINUE |
end DO |
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end DO |
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531 CONTINUE |
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END SUBROUTINE gwprofil |
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RETURN |
end module gwprofil_m |
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END |
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