S. Riette 10/6/2022 Manual inline of compute_entr_detr inside compute_updraft

src/common/turb/mode_compute_entr_detr.F90

-!MNH_LIC Copyright 2009-2021 CNRS, Meteo-France and Universite Paul Sabatier
-!MNH_LIC This is part of the Meso-NH software governed by the CeCILL-C licence
-!MNH_LIC version 1. See LICENSE, CeCILL-C_V1-en.txt and CeCILL-C_V1-fr.txt
-!MNH_LIC for details. version 1.
-!     ######spl
-     MODULE MODE_COMPUTE_ENTR_DETR
-!    ##############################
-!
-IMPLICIT NONE
-CONTAINS
-!     ######spl
-          SUBROUTINE COMPUTE_ENTR_DETR(D, CST, NEB, PARAMMF,&
-                            KK,KKB,KKE,KKL,OTEST,OTESTLCL,&
-                            HFRAC_ICE,PFRAC_ICE,PRHODREF,&
-                            PPRE_MINUS_HALF,&
-                            PPRE_PLUS_HALF,PZZ,PDZZ,&
-                            PTHVM,PTHLM,PRTM,PW_UP2,PTH_UP,&
-                            PTHL_UP,PRT_UP,PLUP,&
-                            PRC_UP,PRI_UP,PTHV_UP,&
-                            PRSAT_UP,PRC_MIX,PRI_MIX,      &
-                            PENTR,PDETR,PENTR_CLD,PDETR_CLD,&
-                            PBUO_INTEG_DRY,PBUO_INTEG_CLD,&
-                            PPART_DRY)
-!         #############################################################
-
-!!
-!!***COMPUTE_ENTR_DETR* - calculates caracteristics of the updraft or downdraft
-!!                       using model of the EDMF scheme 
-!!
-!!    PURPOSE
-!!    -------
-!!****  The purpose of this routine is to compute entrainement and
-!!      detrainement at one level of the updraft
-!
-!!**  METHOD
-!!    ------
-!!
-!!    EXTERNAL
-!!    --------
-!!      
-!!    IMPLICIT ARGUMENTS
-!!    ------------------
-!!
-!!     REFERENCE
-!!     ---------
-!!       Book 1 of Meso-NH documentation (chapter Convection)
-!!       
-!!
-!!     AUTHOR
-!!     ------
-!!    J.Pergaud : 2009
-!!
-!!    MODIFICATIONS
-!!    -------------
-!!      Y.Seity (06/2010) Bug correction
-!!      V.Masson (09/2010) Optimization
-!!      S. Riette april 2011 : ice added, protection against zero divide by Yves Bouteloup
-!!                             protection against too big ZPART_DRY, interface modified
-!!      S. Riette Jan 2012: support for both order of vertical levels
-!!      S. Riette & J. Escobar (11/2013) : remove div by 0 on real*4 case
-!!      P.Marguinaud Jun 2012: fix uninitialized variable
-!!      P.Marguinaud Nov 2012: fix gfortran bug
-!!      S. Riette Apr 2013: bugs correction, rewriting (for optimisation) and
-!!                          improvement of continuity at the condensation level
-!!      S. Riette Nov 2013: protection against zero divide for min value of dry PDETR
-!!      R.Honnert Oct 2016 : Update with AROME
-!  P. Wautelet 08/02/2019: bugfix: compute ZEPSI_CLOUD only once and only when it is needed
-!!      R. El Khatib 29-Apr-2019 portability fix : compiler may get confused by embricked WHERE statements
-!!                          eventually breaking tests with NaN initializations at compile time.
-!!                          Replace by IF conditions and traditional DO loops can only improve the performance.
-!  P. Wautelet 10/02/2021: bugfix: initialized PPART_DRY everywhere
-!! --------------------------------------------------------------------------
-!
-!*      0. DECLARATIONS
-!          ------------
-!
-USE MODD_DIMPHYEX,        ONLY: DIMPHYEX_t
-USE MODD_CST,             ONLY: CST_t
-USE MODD_NEB,             ONLY: NEB_t
-USE MODD_PARAM_MFSHALL_n, ONLY: PARAM_MFSHALL_t
-!
-USE PARKIND1, ONLY : JPRB
-USE YOMHOOK , ONLY : LHOOK, DR_HOOK
-
-IMPLICIT NONE
-!
-!                         
-!*                    1.1  Declaration of Arguments
-!
-!
-TYPE(DIMPHYEX_t),       INTENT(IN)   :: D
-TYPE(CST_t),            INTENT(IN)   :: CST
-TYPE(NEB_t),            INTENT(IN)   :: NEB
-TYPE(PARAM_MFSHALL_t),  INTENT(IN)   :: PARAMMF
-!
-INTEGER,                INTENT(IN)   :: KK
-INTEGER,                INTENT(IN)   :: KKB          ! near ground physical index
-INTEGER,                INTENT(IN)   :: KKE          ! uppest atmosphere physical index
-INTEGER,                INTENT(IN)   :: KKL          ! +1 if grid goes from ground to atmosphere top, -1 otherwise
-LOGICAL,DIMENSION(D%NIT),   INTENT(IN)   :: OTEST ! test to see if updraft is running
-LOGICAL,DIMENSION(D%NIT),   INTENT(IN)   :: OTESTLCL !test of condensation 
-CHARACTER(LEN=1),       INTENT(IN)   :: HFRAC_ICE ! frac_ice can be compute using
-                                              ! Temperature (T) or prescribed
-                                              ! (Y)
-REAL, DIMENSION(D%NIT), INTENT(IN)  :: PFRAC_ICE ! fraction of ice
-!
-!    prognostic variables at t- deltat
-!
-REAL, DIMENSION(D%NIT),     INTENT(IN) ::  PRHODREF  !rhodref
-REAL, DIMENSION(D%NIT),     INTENT(IN) ::  PPRE_MINUS_HALF ! Pressure at flux level KK
-REAL, DIMENSION(D%NIT),     INTENT(IN) ::  PPRE_PLUS_HALF ! Pressure at flux level KK+KKL
-REAL, DIMENSION(D%NIT,D%NKT),   INTENT(IN) ::  PZZ       !  Height at the flux point
-REAL, DIMENSION(D%NIT,D%NKT),   INTENT(IN) ::  PDZZ       !  metrics coefficient
-REAL, DIMENSION(D%NIT,D%NKT),   INTENT(IN) ::  PTHVM      ! ThetaV environment 
-
-!
-!   thermodynamical variables which are transformed in conservative var.
-!
-REAL, DIMENSION(D%NIT,D%NKT), INTENT(IN) ::  PTHLM     ! Thetal
-REAL, DIMENSION(D%NIT,D%NKT), INTENT(IN) ::  PRTM      ! total mixing ratio 
-REAL, DIMENSION(D%NIT,D%NKT), INTENT(IN) ::  PW_UP2    ! Vertical velocity^2
-REAL, DIMENSION(D%NIT),   INTENT(IN)     ::  PTH_UP,PTHL_UP,PRT_UP  ! updraft properties
-REAL, DIMENSION(D%NIT),   INTENT(IN)     ::  PLUP      ! LUP compute from the ground
-REAL, DIMENSION(D%NIT),   INTENT(IN)     ::  PRC_UP,PRI_UP   ! Updraft cloud content
-REAL, DIMENSION(D%NIT),   INTENT(IN)     ::  PTHV_UP ! Thetav of updraft
-REAL, DIMENSION(D%NIT),   INTENT(IN)     ::  PRSAT_UP ! Mixing ratio at saturation in updraft
-REAL, DIMENSION(D%NIT),   INTENT(INOUT)  ::  PRC_MIX, PRI_MIX      ! Mixture cloud content
-REAL, DIMENSION(D%NIT),   INTENT(OUT)    ::  PENTR     ! Mass flux entrainment of the updraft
-REAL, DIMENSION(D%NIT),   INTENT(OUT)    ::  PDETR     ! Mass flux detrainment of the updraft
-REAL, DIMENSION(D%NIT),   INTENT(OUT)    ::  PENTR_CLD ! Mass flux entrainment of the updraft in cloudy part
-REAL, DIMENSION(D%NIT),   INTENT(OUT)    ::  PDETR_CLD ! Mass flux detrainment of the updraft in cloudy part
-REAL, DIMENSION(D%NIT),   INTENT(OUT)    ::  PBUO_INTEG_DRY, PBUO_INTEG_CLD! Integral Buoyancy
-REAL, DIMENSION(D%NIT),   INTENT(OUT)    ::  PPART_DRY ! ratio of dry part at the transition level
-!
-!
-!                       1.2  Declaration of local variables
-!
-!
-
-! Variables for cloudy part
-REAL, DIMENSION(D%NIT) :: ZKIC, ZKIC_F2  ! fraction of env. mass in the muxtures
-REAL, DIMENSION(D%NIT) :: ZEPSI,ZDELTA   ! factor entrainment detrainment
-REAL                   :: ZEPSI_CLOUD    ! factor entrainment detrainment
-REAL                   :: ZCOEFFMF_CLOUD ! factor for compputing entr. detr.
-REAL, DIMENSION(D%NIT) :: ZMIXTHL,ZMIXRT ! Thetal and rt in the mixtures
-REAL, DIMENSION(D%NIT) :: ZTHMIX         ! Theta and Thetav  of mixtures
-REAL, DIMENSION(D%NIT) :: ZRVMIX,ZRCMIX,ZRIMIX ! mixing ratios in mixtures
-REAL, DIMENSION(D%NIT) :: ZTHVMIX, ZTHVMIX_F2 ! Theta and Thetav  of mixtures
-REAL, DIMENSION(D%NIT) :: ZTHV_UP_F2     ! thv_up at flux point kk+kkl
-REAL, DIMENSION(D%NIT) :: ZRSATW, ZRSATI ! working arrays (mixing ratio at saturation)
-REAL, DIMENSION(D%NIT) :: ZTHV           ! theta V of environment at the bottom of cloudy part  
-REAL                   :: ZKIC_INIT      !Initial value of ZKIC
-REAL                   :: ZCOTHVU              ! Variation of Thvup between bottom and top of cloudy part
-
-! Variables for dry part
-REAL                   :: ZFOESW, ZFOESI       ! saturating vapor pressure
-REAL                   :: ZDRSATODP            ! d.Rsat/dP
-REAL                   :: ZT                   ! Temperature
-REAL                   :: ZWK                  ! Work array
-
-! Variables for dry and cloudy parts
-REAL, DIMENSION(D%NIT) :: ZCOEFF_MINUS_HALF,&  ! Variation of Thv between mass points kk-kkl and kk
-                                  ZCOEFF_PLUS_HALF     ! Variation of Thv between mass points kk and kk+kkl
-REAL, DIMENSION(D%NIT) :: ZPRE                 ! pressure at the bottom of the cloudy part
-REAL, DIMENSION(D%NIT) :: ZG_O_THVREF
-REAL, DIMENSION(D%NIT) :: ZFRAC_ICE            ! fraction of ice
-REAL                   :: ZRVORD               ! RV/RD
-REAL, DIMENSION(D%NIT) :: ZDZ_STOP,&           ! Exact Height of the LCL above flux level KK
-                          ZTHV_MINUS_HALF,&    ! Thv at flux point(kk)  
-                          ZTHV_PLUS_HALF       ! Thv at flux point(kk+kkl)
-REAL                   :: ZDZ                  ! Delta Z used in computations
-INTEGER :: JI, JLOOP
-REAL, DIMENSION(D%NIT, 16) :: ZBUF
-REAL(KIND=JPRB) :: ZHOOK_HANDLE
-!----------------------------------------------------------------------------------
-                        
-!                1.3 Initialisation
-!                ------------------
-  IF (LHOOK) CALL DR_HOOK('COMPUTE_ENTR_DETR',0,ZHOOK_HANDLE)
-  
-  ZRVORD   = CST%XRV / CST%XRD   !=1.607
-  ZG_O_THVREF(:)=CST%XG/PTHVM(:,KK)
-  ZCOEFFMF_CLOUD=PARAMMF%XENTR_MF * CST%XG / PARAMMF%XCRAD_MF
-  
-  ZFRAC_ICE(:)=PFRAC_ICE(:) ! to not modify fraction of ice
- 
-  ZPRE(:)=PPRE_MINUS_HALF(:)
-
-!                1.4 Estimation of PPART_DRY
-  DO JLOOP=1,SIZE(OTEST)
-    IF(OTEST(JLOOP) .AND. OTESTLCL(JLOOP)) THEN
-      !No dry part when condensation level is reached
-      PPART_DRY(JLOOP)=0.
-      ZDZ_STOP(JLOOP)=0.
-      ZPRE(JLOOP)=PPRE_MINUS_HALF(JLOOP)
-    ELSE IF (OTEST(JLOOP) .AND. .NOT. OTESTLCL(JLOOP)) THEN
-      !Temperature at flux level KK
-      ZT=PTH_UP(JLOOP)*(PPRE_MINUS_HALF(JLOOP)/CST%XP00) ** (CST%XRD/CST%XCPD)
-      !Saturating vapor pressure at flux level KK
-      ZFOESW = MIN(EXP( CST%XALPW - CST%XBETAW/ZT - CST%XGAMW*LOG(ZT)  ), 0.99*PPRE_MINUS_HALF(JLOOP))
-      ZFOESI = MIN(EXP( CST%XALPI - CST%XBETAI/ZT - CST%XGAMI*LOG(ZT)  ), 0.99*PPRE_MINUS_HALF(JLOOP))
-      !Computation of d.Rsat / dP (partial derivations with respect to P and T
-      !and use of T=Theta*(P/P0)**(R/Cp) to transform dT into dP with theta_up
-      !constant at the vertical)
-      ZDRSATODP=(CST%XBETAW/ZT-CST%XGAMW)*(1-ZFRAC_ICE(JLOOP))+(CST%XBETAI/ZT-CST%XGAMI)*ZFRAC_ICE(JLOOP)
-      ZDRSATODP=((CST%XRD/CST%XCPD)*ZDRSATODP-1.)*PRSAT_UP(JLOOP)/ &
-                  &(PPRE_MINUS_HALF(JLOOP)-(ZFOESW*(1-ZFRAC_ICE(JLOOP)) + ZFOESI*ZFRAC_ICE(JLOOP)))
-      !Use of d.Rsat / dP and pressure at flux level KK to find pressure (ZPRE)
-      !where Rsat is equal to PRT_UP
-      ZPRE(JLOOP)=PPRE_MINUS_HALF(JLOOP)+(PRT_UP(JLOOP)-PRSAT_UP(JLOOP))/ZDRSATODP
-      !Fraction of dry part (computed with pressure and used with heights, no
-      !impact found when using log function here and for pressure on flux levels
-      !computation)
-      PPART_DRY(JLOOP)=MAX(0., MIN(1., (PPRE_MINUS_HALF(JLOOP)-ZPRE(JLOOP))/(PPRE_MINUS_HALF(JLOOP)-PPRE_PLUS_HALF(JLOOP))))
-      !Height above flux level KK of the cloudy part
-      ZDZ_STOP(JLOOP) = (PZZ(JLOOP,KK+KKL)-PZZ(JLOOP,KK))*PPART_DRY(JLOOP)
-    ELSE
-      PPART_DRY(JLOOP)=0. ! value does not matter, here
-    END IF
-  END DO
-
-!               1.5 Gradient and flux values of thetav
-  IF(KK/=KKB)THEN
-    ZCOEFF_MINUS_HALF(:)=((PTHVM(:,KK)-PTHVM(:,KK-KKL))/PDZZ(:,KK))
-    ZTHV_MINUS_HALF(:) = PTHVM(:,KK) - ZCOEFF_MINUS_HALF(:)*0.5*(PZZ(:,KK+KKL)-PZZ(:,KK))
-  ELSE
-    ZCOEFF_MINUS_HALF(:)=0.
-    ZTHV_MINUS_HALF(:) = PTHVM(:,KK)
-  ENDIF
-  ZCOEFF_PLUS_HALF(:)  = ((PTHVM(:,KK+KKL)-PTHVM(:,KK))/PDZZ(:,KK+KKL))
-  ZTHV_PLUS_HALF(:)  = PTHVM(:,KK) + ZCOEFF_PLUS_HALF(:)*0.5*(PZZ(:,KK+KKL)-PZZ(:,KK))
-
-!               2  Dry part computation:
-!                  Integral buoyancy and computation of PENTR and PDETR for dry part
-!               --------------------------------------------------------------------
-
-DO JLOOP=1,SIZE(OTEST)
-  IF (OTEST(JLOOP) .AND. PPART_DRY(JLOOP)>0.) THEN
-    !Buoyancy computation in two parts to use change of gradient of theta v of environment
-    !Between flux level KK and min(mass level, bottom of cloudy part)
-    ZDZ=MIN(ZDZ_STOP(JLOOP),(PZZ(JLOOP,KK+KKL)-PZZ(JLOOP,KK))*0.5)
-    PBUO_INTEG_DRY(JLOOP) = ZG_O_THVREF(JLOOP)*ZDZ*&
-                (0.5 * (  - ZCOEFF_MINUS_HALF(JLOOP))*ZDZ  &
-                  - ZTHV_MINUS_HALF(JLOOP) + PTHV_UP(JLOOP) )
-
-    !Between mass flux KK and bottom of cloudy part (if above mass flux)
-    ZDZ=MAX(0., ZDZ_STOP(JLOOP)-(PZZ(JLOOP,KK+KKL)-PZZ(JLOOP,KK))*0.5)
-    PBUO_INTEG_DRY(JLOOP) = PBUO_INTEG_DRY(JLOOP) + ZG_O_THVREF(JLOOP)*ZDZ*&
-                (0.5 * (  - ZCOEFF_PLUS_HALF(JLOOP))*ZDZ &
-                  - PTHVM(JLOOP,KK) + PTHV_UP(JLOOP) )
-
-    !Entr//Detr. computation
-    IF (PBUO_INTEG_DRY(JLOOP)>=0.) THEN
-      PENTR(JLOOP) = 0.5/(PARAMMF%XABUO-PARAMMF%XBENTR*PARAMMF%XENTR_DRY)*&
-                 LOG(1.+ (2.*(PARAMMF%XABUO-PARAMMF%XBENTR*PARAMMF%XENTR_DRY)/PW_UP2(JLOOP,KK))* &
-                 PBUO_INTEG_DRY(JLOOP))
-      PDETR(JLOOP) = 0.
-    ELSE
-      PENTR(JLOOP) = 0.
-      PDETR(JLOOP) = 0.5/(PARAMMF%XABUO)*&
-                 LOG(1.+ (2.*(PARAMMF%XABUO)/PW_UP2(JLOOP,KK))* &
-                 (-PBUO_INTEG_DRY(JLOOP)))
-    ENDIF
-    PENTR(JLOOP) = PARAMMF%XENTR_DRY*PENTR(JLOOP)/(PZZ(JLOOP,KK+KKL)-PZZ(JLOOP,KK))    
-    PDETR(JLOOP) = PARAMMF%XDETR_DRY*PDETR(JLOOP)/(PZZ(JLOOP,KK+KKL)-PZZ(JLOOP,KK))
-    !Minimum value of detrainment
-    ZWK=PLUP(JLOOP)-0.5*(PZZ(JLOOP,KK)+PZZ(JLOOP,KK+KKL))
-    ZWK=SIGN(MAX(1., ABS(ZWK)), ZWK) ! ZWK must not be zero
-    PDETR(JLOOP) = MAX(PPART_DRY(JLOOP)*PARAMMF%XDETR_LUP/ZWK, PDETR(JLOOP))
-  ELSE
-    !No dry part, condensation reached (OTESTLCL)
-    PBUO_INTEG_DRY(JLOOP) = 0.
-    PENTR(JLOOP)=0.
-    PDETR(JLOOP)=0.
-  ENDIF
-ENDDO
-
-!               3  Wet part computation
-!               -----------------------
-
-!               3.1 Integral buoyancy for cloudy part
-
-  ! Compute theta_v of updraft at flux level KK+KKL                   
-  !MIX variables are used to avoid declaring new variables
-  !but we are dealing with updraft and not mixture
-  ZRCMIX(:)=PRC_UP(:)
-  ZRIMIX(:)=PRI_UP(:)
-  CALL TH_R_FROM_THL_RT(CST,NEB,D%NIT,HFRAC_ICE,ZFRAC_ICE,&
-               PPRE_PLUS_HALF,PTHL_UP,PRT_UP,&
-               ZTHMIX,ZRVMIX,ZRCMIX,ZRIMIX,&
-               ZRSATW, ZRSATI,OOCEAN=.FALSE.,&
-               PBUF=ZBUF)
-  ZTHV_UP_F2(:) = ZTHMIX(:)*(1.+ZRVORD*ZRVMIX(:))/(1.+PRT_UP(:))
-
-  ! Integral buoyancy for cloudy part
-  DO JLOOP=1,SIZE(OTEST)
-    IF(OTEST(JLOOP) .AND. PPART_DRY(JLOOP)<1.) THEN
-      !Gradient of Theta V updraft over the cloudy part, assuming that thetaV updraft don't change
-      !between flux level KK and bottom of cloudy part
-      ZCOTHVU=(ZTHV_UP_F2(JLOOP)-PTHV_UP(JLOOP))/((PZZ(JLOOP,KK+KKL)-PZZ(JLOOP,KK))*(1-PPART_DRY(JLOOP)))
-
-      !Computation in two parts to use change of gradient of theta v of environment
-      !Between bottom of cloudy part (if under mass level) and mass level KK
-      ZDZ=MAX(0., 0.5*(PZZ(JLOOP,KK+KKL)-PZZ(JLOOP,KK))-ZDZ_STOP(JLOOP))
-      PBUO_INTEG_CLD(JLOOP) = ZG_O_THVREF(JLOOP)*ZDZ*&
-              (0.5*( ZCOTHVU - ZCOEFF_MINUS_HALF(JLOOP))*ZDZ &
-                - (PTHVM(JLOOP,KK)-ZDZ*ZCOEFF_MINUS_HALF(JLOOP)) + PTHV_UP(JLOOP) )
-
-      !Between max(mass level, bottom of cloudy part) and flux level KK+KKL
-      ZDZ=(PZZ(JLOOP,KK+KKL)-PZZ(JLOOP,KK))-MAX(ZDZ_STOP(JLOOP),0.5*(PZZ(JLOOP,KK+KKL)-PZZ(JLOOP,KK)))
-      PBUO_INTEG_CLD(JLOOP) = PBUO_INTEG_CLD(JLOOP)+ZG_O_THVREF(JLOOP)*ZDZ*&
-                        (0.5*( ZCOTHVU - ZCOEFF_PLUS_HALF(JLOOP))*ZDZ&
-                - (PTHVM(JLOOP,KK)+(0.5*((PZZ(JLOOP,KK+KKL)-PZZ(JLOOP,KK)))-ZDZ)*ZCOEFF_PLUS_HALF(JLOOP)) +&
-                PTHV_UP(JLOOP) )
-
-    ELSE
-      !No cloudy part
-      PBUO_INTEG_CLD(JLOOP)=0.
-    END IF
-  END DO
-
-!               3.2 Critical mixed fraction for KK+KKL flux level (ZKIC_F2) and
-!                   for bottom of cloudy part (ZKIC), then a mean for the cloudy part
-!                   (put also in ZKIC)
-!
-!                   computation by estimating unknown  
-!                   T^mix r_c^mix and r_i^mix from enthalpy^mix and r_w^mix
-!                   We determine the zero crossing of the linear curve
-!                   evaluating the derivative using ZMIXF=0.1
-                
-  ZKIC_INIT=0.1  ! starting value for critical mixed fraction for CLoudy Part
-
-  !  Compute thetaV of environment at the bottom of cloudy part
-  !    and cons then non cons. var. of mixture at the bottom of cloudy part
-
-  !   JI computed to avoid KKL(KK-KKL) being < KKL*KKB
-JI=KKL*MAX(KKL*(KK-KKL),KKL*KKB)
-DO JLOOP=1,SIZE(OTEST)
-  IF(OTEST(JLOOP) .AND. PPART_DRY(JLOOP)>0.5) THEN
-    ZDZ=ZDZ_STOP(JLOOP)-0.5*(PZZ(JLOOP,KK+KKL)-PZZ(JLOOP,KK))
-    ZTHV(JLOOP)= PTHVM(JLOOP,KK)+ZCOEFF_PLUS_HALF(JLOOP)*ZDZ
-    ZMIXTHL(JLOOP) = ZKIC_INIT * &
-               (PTHLM(JLOOP,KK)+ZDZ*(PTHLM(JLOOP,KK+KKL)-PTHLM(JLOOP,KK))/PDZZ(JLOOP,KK+KKL)) + &
-               (1. - ZKIC_INIT)*PTHL_UP(JLOOP)
-    ZMIXRT(JLOOP)  = ZKIC_INIT * &
-               (PRTM(JLOOP,KK)+ZDZ*(PRTM(JLOOP,KK+KKL)-PRTM(JLOOP,KK))/PDZZ(JLOOP,KK+KKL)) +   &
-               (1. - ZKIC_INIT)*PRT_UP(JLOOP)
-  ELSEIF(OTEST(JLOOP)) THEN
-    ZDZ=0.5*(PZZ(JLOOP,KK+KKL)-PZZ(JLOOP,KK))-ZDZ_STOP(JLOOP)
-    ZTHV(JLOOP)= PTHVM(JLOOP,KK)-ZCOEFF_MINUS_HALF(JLOOP)*ZDZ
-    ZMIXTHL(JLOOP) = ZKIC_INIT * &
-               (PTHLM(JLOOP,KK)-ZDZ*(PTHLM(JLOOP,KK)-PTHLM(JLOOP,JI))/PDZZ(JLOOP,KK)) + &
-               (1. - ZKIC_INIT)*PTHL_UP(JLOOP)
-    ZMIXRT(JLOOP)  = ZKIC_INIT * &
-               (PRTM(JLOOP,KK)-ZDZ*(PRTM(JLOOP,KK)-PRTM(JLOOP,JI))/PDZZ(JLOOP,KK)) + &
-               (1. - ZKIC_INIT)*PRT_UP(JLOOP)
-  ELSE
-#ifdef REPRO55
-    ZMIXTHL(JLOOP) = 0.1
-#else
-    ZMIXTHL(JLOOP) = 300.
-#endif
-    ZMIXRT(JLOOP) = 0.1
-  ENDIF
-ENDDO
-  CALL TH_R_FROM_THL_RT(CST,NEB,D%NIT,HFRAC_ICE,ZFRAC_ICE,&
-               ZPRE,ZMIXTHL,ZMIXRT,&
-               ZTHMIX,ZRVMIX,PRC_MIX,PRI_MIX,&
-               ZRSATW, ZRSATI,OOCEAN=.FALSE.,&
-               PBUF=ZBUF)
-  ZTHVMIX(:) = ZTHMIX(:)*(1.+ZRVORD*ZRVMIX(:))/(1.+ZMIXRT(:))
-
-  !  Compute cons then non cons. var. of mixture at the flux level KK+KKL  with initial ZKIC
-  ZMIXTHL(:) = ZKIC_INIT * 0.5*(PTHLM(:,KK)+PTHLM(:,KK+KKL))+(1. - ZKIC_INIT)*PTHL_UP(:)
-  ZMIXRT(:)  = ZKIC_INIT * 0.5*(PRTM(:,KK)+PRTM(:,KK+KKL))+(1. - ZKIC_INIT)*PRT_UP(:)
-  CALL TH_R_FROM_THL_RT(CST,NEB,D%NIT,HFRAC_ICE,ZFRAC_ICE,&
-               PPRE_PLUS_HALF,ZMIXTHL,ZMIXRT,&
-               ZTHMIX,ZRVMIX,PRC_MIX,PRI_MIX,&
-               ZRSATW, ZRSATI,OOCEAN=.FALSE.,&
-               PBUF=ZBUF)
-  ZTHVMIX_F2(:) = ZTHMIX(:)*(1.+ZRVORD*ZRVMIX(:))/(1.+ZMIXRT(:))
-
-  !Computation of mean ZKIC over the cloudy part
-DO JLOOP=1,SIZE(OTEST)
-  IF (OTEST(JLOOP)) THEN
-    ! Compute ZKIC at the bottom of cloudy part
-    ! Thetav_up at bottom is equal to Thetav_up at flux level KK
-    IF (ABS(PTHV_UP(JLOOP)-ZTHVMIX(JLOOP))<1.E-10) THEN
-      ZKIC(JLOOP)=1.
-    ELSE
-      ZKIC(JLOOP) = MAX(0.,PTHV_UP(JLOOP)-ZTHV(JLOOP))*ZKIC_INIT /  &  
-                 (PTHV_UP(JLOOP)-ZTHVMIX(JLOOP))
-    END IF
-    ! Compute ZKIC_F2 at flux level KK+KKL
-    IF (ABS(ZTHV_UP_F2(JLOOP)-ZTHVMIX_F2(JLOOP))<1.E-10) THEN
-      ZKIC_F2(JLOOP)=1.
-    ELSE
-      ZKIC_F2(JLOOP) = MAX(0.,ZTHV_UP_F2(JLOOP)-ZTHV_PLUS_HALF(JLOOP))*ZKIC_INIT /  &  
-                 (ZTHV_UP_F2(JLOOP)-ZTHVMIX_F2(JLOOP))
-    END IF
-    !Mean ZKIC over the cloudy part
-    ZKIC(JLOOP)=MAX(MIN(0.5*(ZKIC(JLOOP)+ZKIC_F2(JLOOP)),1.),0.)
-  END IF
-END DO
-
-!               3.3 Integration of PDF
-!                   According to Kain and Fritsch (1990), we replace delta Mt
-!                   in eq. (7) and (8) using eq. (5). Here we compute the ratio
-!                   of integrals without computing delta Me
-
-  !Constant PDF
-  !For this PDF, eq. (5) is delta Me=0.5*delta Mt
-DO JLOOP=1,SIZE(OTEST)
-  IF(OTEST(JLOOP)) THEN
-    ZEPSI(JLOOP) = ZKIC(JLOOP)**2. !integration multiplied by 2
-    ZDELTA(JLOOP) = (1.-ZKIC(JLOOP))**2. !idem
-  ENDIF
-ENDDO
-
-  !Triangular PDF
-  !Calculus must be verified before activating this part, but in this state,
-  !results on ARM case are almost identical
-  !For this PDF, eq. (5) is also delta Me=0.5*delta Mt
-  !WHERE(OTEST)
-  !  !Integration multiplied by 2
-  !  WHERE(ZKIC<0.5)
-  !    ZEPSI(:)=8.*ZKIC(:)**3/3.
-  !    ZDELTA(:)=1.-4.*ZKIC(:)**2+8.*ZKIC(:)**3/3.
-  !  ELSEWHERE
-  !    ZEPSI(:)=5./3.-4*ZKIC(:)**2+8.*ZKIC(:)**3/3.
-  !    ZDELTA(:)=8.*(1.-ZKIC(:))**3/3.
-  !  ENDWHERE
-  !ENDWHERE
-
-!               3.4 Computation of PENTR and PDETR
-DO JLOOP=1,SIZE(OTEST)
-  IF(OTEST(JLOOP)) THEN
-    ZEPSI_CLOUD=MIN(ZDELTA(JLOOP), ZEPSI(JLOOP))
-    PENTR_CLD(JLOOP) = (1.-PPART_DRY(JLOOP))*ZCOEFFMF_CLOUD*PRHODREF(JLOOP)*ZEPSI_CLOUD
-    PDETR_CLD(JLOOP) = (1.-PPART_DRY(JLOOP))*ZCOEFFMF_CLOUD*PRHODREF(JLOOP)*ZDELTA(JLOOP)
-    PENTR(JLOOP) = PENTR(JLOOP)+PENTR_CLD(JLOOP)
-    PDETR(JLOOP) = PDETR(JLOOP)+PDETR_CLD(JLOOP)
-  ELSE
-    PENTR_CLD(JLOOP) = 0.
-    PDETR_CLD(JLOOP) = 0.
-  ENDIF
-ENDDO
-
-IF (LHOOK) CALL DR_HOOK('COMPUTE_ENTR_DETR',1,ZHOOK_HANDLE)
-CONTAINS
-INCLUDE "th_r_from_thl_rt.func.h"
-INCLUDE "compute_frac_ice.func.h"
-END SUBROUTINE COMPUTE_ENTR_DETR
-END MODULE MODE_COMPUTE_ENTR_DETR