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MODULE MODE_COMPUTE_BL89_ML
IMPLICIT NONE
CONTAINS
RODIER Quentin
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! ######spl
SUBROUTINE COMPUTE_BL89_ML(KKA,KKB,KKE,KKU,KKL,PDZZ2D, &
PTKEM_DEP,PG_O_THVREF,PVPT,KK,OUPORDN,OFLUX,PSHEAR,PLWORK)
USE PARKIND1, ONLY : JPRB
USE YOMHOOK , ONLY : LHOOK, DR_HOOK
! ###################################################################
!!
!! COMPUTE_BL89_ML routine to:
!! 1/ compute upward or downward mixing length with BL89 formulation
!!
!! AUTHOR
!! ------
!! J. PERGAUD
!!
!! MODIFICATIONS
!! -------------
!! Original 19/01/06
!! S. Riette Jan 2012: support for both order of vertical levels and cleaning
!! R.Honnert Oct 2016 : Update with AROME
!! Q.Rodier 01/2019 : support RM17 mixing length as in bl89.f90
! P. Wautelet 10/04/2019: replace ABORT and STOP calls by Print_msg
!!
!-------------------------------------------------------------------------------
!
!* 0. DECLARATIONS
!
! ------------
!
!!!!!!!!!!!!
!!!!!!!!!!!!
!!!!!!!!!!!!!!!!!! WARNING !!
!!!!!!!!!!!!
!!!!!!!!!!!!
!Any modification done to this routine must be copied in bl89.f90.
!This routine was inlined in bl89 for numerical performance reasons
!but algorithm must remain the same.
!!!!!!!!!!!!
!
USE MODD_CTURB
USE MODD_PARAMETERS, ONLY: JPVEXT
!
USE MODE_MSG
!
USE MODI_SHUMAN_MF, ONLY: DZM_MF, MZM_MF
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!
IMPLICIT NONE
!
! 0.1 arguments
!
INTEGER, INTENT(IN) :: KKA ! near ground array index
INTEGER, INTENT(IN) :: KKB ! near ground physical index
INTEGER, INTENT(IN) :: KKE ! uppest atmosphere physical index
INTEGER, INTENT(IN) :: KKU ! uppest atmosphere array index
INTEGER, INTENT(IN) :: KKL ! +1 if grid goes from ground to atmosphere top, -1 otherwise
REAL, DIMENSION(:,:), INTENT(IN) :: PDZZ2D ! height difference between two mass levels
REAL, DIMENSION(:), INTENT(IN) :: PTKEM_DEP ! TKE to consume
REAL, DIMENSION(:), INTENT(IN) :: PG_O_THVREF ! g/ThetaVRef at the departure point
REAL, DIMENSION(:,:), INTENT(IN) :: PVPT ! ThetaV on mass levels
INTEGER, INTENT(IN) :: KK ! index of departure level
LOGICAL, INTENT(IN) :: OUPORDN ! switch to compute upward (true) or
! downward (false) mixing length
LOGICAL, INTENT(IN) :: OFLUX ! Computation must be done from flux level
REAL, DIMENSION(:), INTENT(OUT) :: PLWORK ! Resulting mixing length
REAL, DIMENSION(:,:), INTENT(IN) :: PSHEAR ! vertical wind shear for RM17 mixing length
! 0.2 Local variable
!
REAL, DIMENSION(SIZE(PVPT,1)) :: ZLWORK1,ZLWORK2 ! Temporary mixing length
REAL, DIMENSION(SIZE(PVPT,1)) :: ZINTE,ZPOTE ! TKE and potential energy
! between 2 levels
REAL, DIMENSION(SIZE(PVPT,1)) :: ZVPT_DEP ! Thetav on departure point
!
REAL, DIMENSION(SIZE(PVPT,1),SIZE(PVPT,2)) :: ZDELTVPT,ZHLVPT
!Virtual Potential Temp at Half level and DeltaThv between
!2 mass levels
INTEGER :: IIJU !Internal Domain
INTEGER :: J1D !horizontal loop counter
INTEGER :: JKK !loop counters
REAL :: ZTEST,ZTEST0,ZTESTM !test for vectorization
!-------------------------------------------------------------------------------------
!
!* 1. INITIALISATION
! --------------
REAL(KIND=JPRB) :: ZHOOK_HANDLE
IF (LHOOK) CALL DR_HOOK('COMPUTE_BL89_ML',0,ZHOOK_HANDLE)
IIJU=SIZE(PVPT,1)
!
ZDELTVPT(:,:)=DZM_MF(PVPT(:,:), KKA, KKU, KKL)
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ZDELTVPT(:,KKA)=0.
WHERE (ABS(ZDELTVPT(:,:))<XLINF)
ZDELTVPT(:,:)=XLINF
END WHERE
!
ZHLVPT(:,:)=MZM_MF(PVPT(:,:), KKA, KKU, KKL)
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!
!We consider that gradient between mass levels KKB and KKB+KKL is the same as
!the gradient between flux level KKB and mass level KKB
ZDELTVPT(:,KKB)=PDZZ2D(:,KKB)*ZDELTVPT(:,KKB+KKL)/PDZZ2D(:,KKB+KKL)
ZHLVPT(:,KKB)=PVPT(:,KKB)-ZDELTVPT(:,KKB)*0.5
!
!
!
!* 2. CALCULATION OF THE UPWARD MIXING LENGTH
! ---------------------------------------
!
IF (OUPORDN.EQV..TRUE.) THEN
ZINTE(:)=PTKEM_DEP(:)
PLWORK=0.
ZTESTM=1.
IF(OFLUX)THEN
ZVPT_DEP(:)=ZHLVPT(:,KK) ! departure point is on flux level
!We must compute what happens between flux level KK and mass level KK
DO J1D=1,IIJU
ZTEST0=0.5+SIGN(0.5,ZINTE(J1D)) ! test if there's energy to consume
! Energy consumed if parcel cross the entire layer
ZPOTE(J1D) = ZTEST0*(PG_O_THVREF(J1D) * &
(0.5*(ZHLVPT(J1D,KK)+ PVPT(J1D,KK)) - ZVPT_DEP(J1D)) + &
XRM17*PSHEAR(J1D,KK)*SQRT(ABS(PTKEM_DEP(J1D)))) * &
PDZZ2D(J1D,KK)*0.5
! Test if it rests some energy to consume
ZTEST =0.5+SIGN(0.5,ZINTE(J1D)-ZPOTE(J1D))
! Length travelled by parcel if it rests energy to consume
ZLWORK1(J1D)=PDZZ2D(J1D,KK)*0.5
! Lenght travelled by parcel to nullify energy
ZLWORK2(J1D)= ( - PG_O_THVREF(J1D) * &
( ZHLVPT(J1D,KK) - ZVPT_DEP(J1D) ) &
- XRM17*PSHEAR(J1D,KK)*SQRT(ABS(PTKEM_DEP(J1D))) &
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+ SQRT (ABS( &
(XRM17*PSHEAR(J1D,KK)*SQRT(ABS(PTKEM_DEP(J1D))) + &
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PG_O_THVREF(J1D) * (ZHLVPT(J1D,KK) - ZVPT_DEP(J1D)) )**2 &
+ 2. * ZINTE(J1D) * PG_O_THVREF(J1D) &
* ZDELTVPT(J1D,KK) / PDZZ2D(J1D,KK) )) ) / &
( PG_O_THVREF(J1D) * ZDELTVPT(J1D,KK) / PDZZ2D(J1D,KK) )
! Effective length travelled by parcel
PLWORK(J1D)=PLWORK(J1D)+ZTEST0*(ZTEST*ZLWORK1(J1D)+ &
(1-ZTEST)*ZLWORK2(J1D))
! Rest of energy to consume
ZINTE(J1D) = ZINTE(J1D) - ZPOTE(J1D)
ENDDO
ELSE
ZVPT_DEP(:)=PVPT(:,KK) ! departure point is on mass level
ENDIF
DO JKK=KK+KKL,KKE,KKL
IF(ZTESTM > 0.) THEN
ZTESTM=0
DO J1D=1,IIJU
ZTEST0=0.5+SIGN(0.5,ZINTE(J1D))
ZPOTE(J1D) = ZTEST0*(PG_O_THVREF(J1D) * &
(ZHLVPT(J1D,JKK) - ZVPT_DEP(J1D)) &
+ XRM17*PSHEAR(J1D,JKK)*SQRT(ABS(PTKEM_DEP(J1D))))* PDZZ2D(J1D,JKK)
ZTEST =0.5+SIGN(0.5,ZINTE(J1D)-ZPOTE(J1D))
ZTESTM=ZTESTM+ZTEST0
ZLWORK1(J1D)=PDZZ2D(J1D,JKK)
!ZLWORK2 jump of the last reached level
ZLWORK2(J1D)= ( - PG_O_THVREF(J1D) * &
( PVPT(J1D,JKK-KKL) - ZVPT_DEP(J1D) ) &
- XRM17*PSHEAR(J1D,JKK)*sqrt(abs(PTKEM_DEP(J1D))) &
+ SQRT (ABS( &
(XRM17*PSHEAR(J1D,JKK)*sqrt(abs(PTKEM_DEP(J1D))) + &
PG_O_THVREF(J1D) * (PVPT(J1D,JKK-KKL) - ZVPT_DEP(J1D)) )**2 &
+ 2. * ZINTE(J1D) * PG_O_THVREF(J1D) &
* ZDELTVPT(J1D,JKK) / PDZZ2D(J1D,JKK) )) ) / &
( PG_O_THVREF(J1D) * ZDELTVPT(J1D,JKK) / PDZZ2D(J1D,JKK) )
!
PLWORK(J1D)=PLWORK(J1D)+ZTEST0*(ZTEST*ZLWORK1(J1D)+ &
(1-ZTEST)*ZLWORK2(J1D))
ZINTE(J1D) = ZINTE(J1D) - ZPOTE(J1D)
END DO
ENDIF
END DO
ENDIF
!!
!* 2. CALCULATION OF THE DOWNWARD MIXING LENGTH
! ---------------------------------------
!
IF (OUPORDN.EQV..FALSE.) THEN
IF(OFLUX) CALL PRINT_MSG(NVERB_FATAL,'GEN','COMPUTE_BL89_ML','OFLUX option not coded for downward mixing length')
ZINTE(:)=PTKEM_DEP(:)
PLWORK=0.
ZTESTM=1.
DO JKK=KK,KKB,-KKL
IF(ZTESTM > 0.) THEN
ZTESTM=0
DO J1D=1,IIJU
ZTEST0=0.5+SIGN(0.5,ZINTE(J1D))
ZPOTE(J1D) = ZTEST0*(-PG_O_THVREF(J1D) * &
(ZHLVPT(J1D,JKK) - PVPT(J1D,KK)) &
+ XRM17*PSHEAR(J1D,JKK)*SQRT(ABS(PTKEM_DEP(J1D))))* PDZZ2D(J1D,JKK)
ZTEST =0.5+SIGN(0.5,ZINTE(J1D)-ZPOTE(J1D))
ZTESTM=ZTESTM+ZTEST0
ZLWORK1(J1D)=PDZZ2D(J1D,JKK)
ZLWORK2(J1D)= ( + PG_O_THVREF(J1D) * &
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( PVPT(J1D,JKK) - PVPT(J1D,KK) ) &
-XRM17*PSHEAR(J1D,JKK)*sqrt(abs(PTKEM_DEP(J1D))) &
+ SQRT (ABS( &
(XRM17*PSHEAR(J1D,JKK)*sqrt(abs(PTKEM_DEP(J1D))) - &
PG_O_THVREF(J1D) * (PVPT(J1D,JKK) - PVPT(J1D,KK)) )**2 &
+ 2. * ZINTE(J1D) * PG_O_THVREF(J1D) &
* ZDELTVPT(J1D,JKK) / PDZZ2D(J1D,JKK) )) ) / &
( PG_O_THVREF(J1D) * ZDELTVPT(J1D,JKK) / PDZZ2D(J1D,JKK) )
!
PLWORK(J1D)=PLWORK(J1D)+ZTEST0*(ZTEST*ZLWORK1(J1D)+ &
(1-ZTEST)*ZLWORK2(J1D))
ZINTE(J1D) = ZINTE(J1D) - ZPOTE(J1D)
END DO
ENDIF
END DO
ENDIF
IF (LHOOK) CALL DR_HOOK('COMPUTE_BL89_ML',1,ZHOOK_HANDLE)
END SUBROUTINE COMPUTE_BL89_ML
END MODULE MODE_COMPUTE_BL89_ML