write_lesn.f90

!MNH_LIC Copyright 1994-2013 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 LICENCE, CeCILL-C_V1-en.txt and CeCILL-C_V1-fr.txt  
!MNH_LIC for details. version 1.
! $Source$
!-----------------------------------------------------------------
!######################
MODULE MODI_WRITE_LES_n
!######################
!
INTERFACE
!
      SUBROUTINE  WRITE_LES_n(HLES_AVG)
!
CHARACTER(LEN=1), INTENT(IN) :: HLES_AVG ! flag to perform the averages
!                                        ! or normalizations
END SUBROUTINE WRITE_LES_n
!
END INTERFACE
!
END MODULE MODI_WRITE_LES_n

!     ######################
      SUBROUTINE  WRITE_LES_n(HLES_AVG)
!     ######################
!
!
!!****  *WRITE_LES_n* writes the LES final diagnostics for model _n 
!!                         
!!
!!    PURPOSE
!!    -------
!!
!!    EXTERNAL
!!    --------
!!
!!    IMPLICIT ARGUMENTS
!!    ------------------
!!
!!    REFERENCE
!!    ---------
!!
!!    AUTHOR
!!    ------
!!      V. Masson
!!
!!    MODIFICATIONS
!!    -------------
!!      Original         07/02/00
!!                       01/02/01 (D. Gazen) add module MODD_NSV for NSV variable
!!                       06/11/02 (V. Masson) some minor bugs
!!                       01/04/03 (V. Masson) idem
!!                       10/10/09 (P. Aumond) Add user multimaskS
!!
!! --------------------------------------------------------------------------
!       
!*      0. DECLARATIONS
!          ------------
!
USE MODD_CST
USE MODD_LES
USE MODD_LES_n
USE MODD_FIELD_n
USE MODD_CONF_n
USE MODD_PARAM_n
USE MODD_TURB_n
USE MODD_GRID_n
USE MODD_NSV, ONLY : NSV
!
USE MODD_LUNIT_n
!
USE MODE_ll
USE MODE_FM
!
USE MODE_LES_DIACHRO
USE MODE_MODELN_HANDLER
!
USE MODI_WRITE_LES_BUDGET_n
USE MODI_WRITE_LES_RT_BUDGET_n
USE MODI_WRITE_LES_SV_BUDGET_n
!
USE MODI_LES_SPEC_N
!
IMPLICIT NONE
!
!
!*      0.1  declarations of arguments
!
CHARACTER(LEN=1), INTENT(IN) :: HLES_AVG ! flag to perform the averages
!                                        ! or normalizations
!
!
!*      0.2  declaration of local variables
!
INTEGER :: IRESP, ILUOUT
INTEGER :: IMASK
!
INTEGER :: JSV       ! scalar loop counter
INTEGER :: JI        ! loop counter
INTEGER :: JPDF      ! pdf loop counter
!
CHARACTER(len=9), DIMENSION(NLES_MASKS) :: YSUBTITLE
CHARACTER(len=5)                        :: YGROUP
!
REAL, DIMENSION(:,:,:), ALLOCATABLE     :: ZAVG_PTS_ll
REAL, DIMENSION(:,:,:), ALLOCATABLE     :: ZUND_PTS_ll
REAL                                    :: ZCART_PTS_ll
INTEGER                                 :: IMI ! Current model inde
!
!
!-------------------------------------------------------------------------------
!
IF (.NOT. LLES) RETURN
!
IF (HLES_AVG=='A'                                                       &
     .AND. (XLES_TEMP_MEAN_START==XUNDEF .OR. XLES_TEMP_MEAN_END==XUNDEF)) RETURN
IF (HLES_AVG=='E' .AND. CLES_NORM_TYPE=='NONE'                          ) RETURN
IF (HLES_AVG=='H' .AND. (CLES_NORM_TYPE=='NONE'                          &
     .OR. XLES_TEMP_MEAN_START/=XUNDEF .OR. XLES_TEMP_MEAN_END/=XUNDEF)) RETURN
!
!*      1.   Initializations
!            ---------------
!
IMI = GET_CURRENT_MODEL_INDEX()
!
CALL FMLOOK_ll(CLUOUT,CLUOUT,ILUOUT,IRESP)
!
!
!*      1.1  Normalization variables
!            -----------------------
!
IF (CLES_NORM_TYPE/='NONE' ) THEN
  ALLOCATE(XLES_NORM_M  (NLES_TIMES))
  ALLOCATE(XLES_NORM_S  (NLES_TIMES))
  ALLOCATE(XLES_NORM_K  (NLES_TIMES))
  ALLOCATE(XLES_NORM_RHO(NLES_TIMES))
  ALLOCATE(XLES_NORM_RV (NLES_TIMES))
  ALLOCATE(XLES_NORM_SV (NLES_TIMES,NSV))
  ALLOCATE(XLES_NORM_P  (NLES_TIMES))
  !
  IF (CLES_NORM_TYPE=='CONV') THEN
    WHERE (XLES_WSTAR(:)>0.)
      XLES_NORM_M(:)   = XLES_BL_HEIGHT(:)
      XLES_NORM_S(:)   = XLES_NORM_M(:) / XLES_WSTAR(:)
      XLES_NORM_K(:)   = XLES_Q0(:) / XLES_WSTAR(:)
      XLES_NORM_RHO(:) = XLES_MEAN_RHO(1,:,1)
      XLES_NORM_RV(:)  = XLES_E0(:) / XLES_WSTAR(:)
      XLES_NORM_P(:)   = XLES_MEAN_RHO(1,:,1) * XLES_WSTAR(:)**2
    ELSEWHERE
      XLES_NORM_M(:)   = 0.
      XLES_NORM_S(:)   = 0.
      XLES_NORM_K(:)   = 0.
      XLES_NORM_RHO(:) = 0.
      XLES_NORM_RV(:)  = 0.
      XLES_NORM_P(:)   = 0.
    END WHERE
    DO JSV=1,NSV
      WHERE (XLES_WSTAR(:)>0.)
        XLES_NORM_SV(:,JSV)= XLES_SV0(:,JSV) / XLES_WSTAR(:)
      ELSEWHERE
        XLES_NORM_SV(:,JSV)= 0.
      END WHERE
    END DO
  ELSE IF (CLES_NORM_TYPE=='EKMA') THEN
    WHERE (XLES_USTAR(:)>0.)
      XLES_NORM_M(:)   = XLES_BL_HEIGHT(:)
      XLES_NORM_S(:)   = XLES_NORM_M(:) / XLES_USTAR(:)
      XLES_NORM_K(:)   = XLES_Q0(:) / XLES_USTAR(:)
      XLES_NORM_RHO(:) = XLES_MEAN_RHO(1,:,1)
      XLES_NORM_RV(:)  = XLES_E0(:) / XLES_USTAR(:)
      XLES_NORM_P(:)   = XLES_MEAN_RHO(1,:,1) * XLES_USTAR(:)**2
    ELSEWHERE
      XLES_NORM_M(:)   = 0.
      XLES_NORM_S(:)   = 0.
      XLES_NORM_K(:)   = 0.
      XLES_NORM_RHO(:) = 0.
      XLES_NORM_RV(:)  = 0.
      XLES_NORM_P(:)   = 0.
    END WHERE
    DO JSV=1,NSV
      WHERE (XLES_USTAR(:)>0.)
        XLES_NORM_SV(:,JSV)= XLES_SV0(:,JSV) / XLES_USTAR(:)
      ELSEWHERE
        XLES_NORM_SV(:,JSV)= 0.
      END WHERE
    END DO
  ELSE IF (CLES_NORM_TYPE=='MOBU') THEN
    XLES_NORM_M(:) = XLES_MO_LENGTH(:)
    WHERE (XLES_USTAR(:)>0.)
      XLES_NORM_S(:)   = XLES_NORM_M(:) / XLES_USTAR(:)
      XLES_NORM_K(:)   = XLES_Q0(:) / XLES_USTAR(:)
      XLES_NORM_RHO(:) = XLES_MEAN_RHO(1,:,1)
      XLES_NORM_RV(:)  = XLES_E0(:) / XLES_USTAR(:)
      XLES_NORM_P(:)   = XLES_MEAN_RHO(1,:,1) * XLES_USTAR(:)**2
    ELSEWHERE
      XLES_NORM_S(:)   = 0.
      XLES_NORM_K(:)   = 0.
      XLES_NORM_RHO(:) = 0.
      XLES_NORM_RV(:)  = 0.
      XLES_NORM_P(:)   = 0.
    END WHERE
    DO JSV=1,NSV
      WHERE (XLES_USTAR(:)>0.)
        XLES_NORM_SV(:,JSV)= XLES_SV0(:,JSV) / XLES_USTAR(:)
      ELSEWHERE
        XLES_NORM_SV(:,JSV)= 0.
      END WHERE
    END DO
  END IF
END IF
!
!*      1.2  Initializations for WRITE_DIACHRO
!            ---------------------------------
!
NLES_CURRENT_TIMES=NLES_TIMES
!
ALLOCATE(XLES_CURRENT_TRAJT(NLES_TIMES,1))
XLES_CURRENT_TRAJT(:,:) = XLES_TRAJT(:,:)
ALLOCATE(XLES_CURRENT_Z(NLES_K))
XLES_CURRENT_Z(:) = XLES_Z(:)
ALLOCATE(XLES_CURRENT_DATIME(16,NLES_TIMES))
XLES_CURRENT_DATIME(:,:) = XLES_DATIME(:,:)
!
XLES_CURRENT_ZS = XLES_ZS
!
NLES_CURRENT_IINF=NLESn_IINF(IMI)
NLES_CURRENT_ISUP=NLESn_ISUP(IMI)
NLES_CURRENT_JINF=NLESn_JINF(IMI)
NLES_CURRENT_JSUP=NLESn_JSUP(IMI)
!
XLES_CURRENT_DOMEGAX=XDXHAT(1)
XLES_CURRENT_DOMEGAY=XDYHAT(1)
!
CCURRENT_FMDIAC = CFMDIAC
!
!
!*      2.   (z,t) profiles (all masks)
!            --------------
IMASK = 1
YSUBTITLE(IMASK) = " (cart)"
IF (LLES_NEB_MASK) THEN
  IMASK=IMASK+1
  YSUBTITLE(IMASK) = " (neb)"
  IMASK=IMASK+1
  YSUBTITLE(IMASK) = " (clear)"
END IF
IF (LLES_CORE_MASK) THEN
  IMASK=IMASK+1
  YSUBTITLE(IMASK) = " (core)"
  IMASK=IMASK+1
  YSUBTITLE(IMASK) = " (env)"
END IF
IF (LLES_MY_MASK) THEN
   DO JI=1,NLES_MASKS_USER
        IMASK=IMASK+1
        YSUBTITLE(IMASK) = " (user)"
   END DO
END IF
IF (LLES_CS_MASK) THEN
  IMASK=IMASK+1
  YSUBTITLE(IMASK) = " (cs1)"
  IMASK=IMASK+1
  YSUBTITLE(IMASK) = " (cs2)"
  IMASK=IMASK+1
  YSUBTITLE(IMASK) = " (cs3)"
END IF
!
!*      2.0  averaging diagnostics
!            ---------------------
!
IF (HLES_AVG==' ' .OR. HLES_AVG=='A') THEN
  ALLOCATE(ZAVG_PTS_ll (NLES_K,NLES_TIMES,NLES_MASKS))
  ALLOCATE(ZUND_PTS_ll (NLES_K,NLES_TIMES,NLES_MASKS))
  !
  ZAVG_PTS_ll(:,:,:) = NLES_AVG_PTS_ll(:,:,:)
  ZUND_PTS_ll(:,:,:) = NLES_UND_PTS_ll(:,:,:)
  ZCART_PTS_ll       = (NLESn_ISUP(IMI)-NLESn_IINF(IMI)+1) * (NLESn_JSUP(IMI)-NLESn_JINF(IMI)+1)
  !
  CALL LES_DIACHRO_MASKS("AVG_PTS  ",YSUBTITLE(:), &
  "number of points used for averaging"//YSUBTITLE(:),"-",ZAVG_PTS_ll,HLES_AVG)
  CALL LES_DIACHRO_MASKS("AVG_PTSF",YSUBTITLE(:), &
  "fraction of points used for averaging"//YSUBTITLE(:),"-",ZAVG_PTS_ll/ZCART_PTS_ll,HLES_AVG)
  CALL LES_DIACHRO_MASKS("UND_PTS  ",YSUBTITLE(:), &
  "number of points below orography"//YSUBTITLE(:),"-",ZUND_PTS_ll,HLES_AVG)
  CALL LES_DIACHRO_MASKS("UND_PTSF",YSUBTITLE(:), &
  "fraction of points below orography"//YSUBTITLE(:),"-",ZUND_PTS_ll/ZCART_PTS_ll,HLES_AVG)
  !
  DEALLOCATE(ZAVG_PTS_ll)
  DEALLOCATE(ZUND_PTS_ll)
END IF
!
!
!*      2.1  mean quantities
!            ---------------
!
CALL LES_DIACHRO_MASKS("MEAN_U  ",YSUBTITLE(:), &
  "Mean U Profile"//YSUBTITLE(:)," m/s",XLES_MEAN_U,HLES_AVG)

CALL LES_DIACHRO_MASKS("MEAN_V  ",YSUBTITLE(:), &
  "Mean V Profile"//YSUBTITLE(:)," m/s",XLES_MEAN_V,HLES_AVG)

CALL LES_DIACHRO_MASKS("MEAN_W  ",YSUBTITLE(:), &
  "Mean W Profile"//YSUBTITLE(:)," m/s",XLES_MEAN_W,HLES_AVG)

CALL LES_DIACHRO_MASKS("MEAN_PRE",YSUBTITLE(:), &
  "Mean pressure Profile"//YSUBTITLE(:)," Pa",XLES_MEAN_P,HLES_AVG)

CALL LES_DIACHRO_MASKS("MEAN_RHO",YSUBTITLE(:), &
  "Mean density Profile"//YSUBTITLE(:)," kg/m3",XLES_MEAN_RHO,HLES_AVG)

CALL LES_DIACHRO_MASKS("MEAN_TH ",YSUBTITLE(:),&
  "Mean potential temperature Profile"//YSUBTITLE(:)," K",XLES_MEAN_Th,HLES_AVG)

CALL LES_DIACHRO_MASKS("MEAN_MF ",YSUBTITLE(:),&
  "Mass-flux Profile"//YSUBTITLE(:)," m s-1",XLES_MEAN_Mf,HLES_AVG)

IF (LUSERC) &
CALL LES_DIACHRO_MASKS("MEAN_THL",YSUBTITLE(:), &
   "Mean liquid potential temperature Profile"//YSUBTITLE(:)," K",XLES_MEAN_Thl,HLES_AVG)

IF (LUSERV) &
CALL LES_DIACHRO_MASKS("MEAN_THV",YSUBTITLE(:), &
   "Mean virtual potential temperature Profile"//YSUBTITLE(:)," K",XLES_MEAN_Thv,HLES_AVG)

IF (LUSERC) &
CALL LES_DIACHRO_MASKS("MEAN_RT ",YSUBTITLE(:), &
  "Mean Rt Profile"//YSUBTITLE(:)," kg/kg",XLES_MEAN_Rt,HLES_AVG)

IF (LUSERV) &
CALL LES_DIACHRO_MASKS("MEAN_RV ",YSUBTITLE(:), &
  "Mean Rv Profile"//YSUBTITLE(:)," kg/kg",XLES_MEAN_Rv,HLES_AVG)

IF (LUSERV) &
CALL LES_DIACHRO_MASKS("MEAN_REHU ",YSUBTITLE(:), &
  "Mean Rh Profile"//YSUBTITLE(:)," %",XLES_MEAN_Rehu,HLES_AVG)

IF (LUSERV) &
CALL LES_DIACHRO_MASKS("MEAN_QS ",YSUBTITLE(:), &
  "Mean Qs Profile"//YSUBTITLE(:)," kg/kg",XLES_MEAN_Qs,HLES_AVG)

IF (LUSERC) &
CALL LES_DIACHRO_MASKS("MEAN_KHT ",YSUBTITLE(:),&
  "Eddy-diffusivity (temperature) Profile"//YSUBTITLE(:)," m2 s-1",XLES_MEAN_KHt,HLES_AVG)

IF (LUSERC) &
CALL LES_DIACHRO_MASKS("MEAN_KHR ",YSUBTITLE(:),&
  "Eddy-diffusivity (wvapor) Profile"//YSUBTITLE(:)," m2 s-1",XLES_MEAN_KHr,HLES_AVG)  

IF (LUSERC) &
CALL LES_DIACHRO_MASKS("MEAN_RC ",YSUBTITLE(:), &
  "Mean Rc Profile"//YSUBTITLE(:)," kg/kg",XLES_MEAN_Rc,HLES_AVG)

IF (LUSERC) &
CALL LES_DIACHRO_MASKS("MEAN_CF ",YSUBTITLE(:), &
  "Mean Cf Profile"//YSUBTITLE(:)," ",XLES_MEAN_Cf,HLES_AVG)

IF (LUSERC) &
CALL LES_DIACHRO_MASKS("MEAN_INDCF ",YSUBTITLE(:), &
  "Mean Cf>1-6 Profile (0 ou 1)"//YSUBTITLE(:)," ",XLES_MEAN_INDCf,HLES_AVG)

IF (LUSERC) &
CALL LES_DIACHRO_MASKS("MEAN_INDCF2 ",YSUBTITLE(:), &
  "Mean Cf>1-5 Profile (0 ou 1)"//YSUBTITLE(:)," ",XLES_MEAN_INDCf2,HLES_AVG)

IF (LUSERR) &
CALL LES_DIACHRO_MASKS("MEAN_RR ",YSUBTITLE(:), &
  "Mean Rr Profile"//YSUBTITLE(:)," kg/kg",XLES_MEAN_Rr,HLES_AVG)

IF (LUSERI) &
CALL LES_DIACHRO_MASKS("MEAN_RI ",YSUBTITLE(:), &
  "Mean Ri Profile"//YSUBTITLE(:)," kg/kg",XLES_MEAN_Ri,HLES_AVG)

IF (LUSERS) &
CALL LES_DIACHRO_MASKS("MEAN_RS ",YSUBTITLE(:), &
  "Mean Rs Profile"//YSUBTITLE(:)," kg/kg",XLES_MEAN_Rs,HLES_AVG)

IF (LUSERG) &
CALL LES_DIACHRO_MASKS("MEAN_RG ",YSUBTITLE(:), &
  "Mean Rg Profile"//YSUBTITLE(:)," kg/kg",XLES_MEAN_Rg,HLES_AVG)

IF (LUSERH) &
CALL LES_DIACHRO_MASKS("MEAN_RH ",YSUBTITLE(:), &
  "Mean Rh Profile"//YSUBTITLE(:)," kg/kg",XLES_MEAN_Rh,HLES_AVG)

IF (NSV>0) &
CALL LES_DIACHRO_SV_MASKS("MEAN_SV ",YSUBTITLE(:), &
  "Mean Sv Profiles"//YSUBTITLE(:)," kg/kg",XLES_MEAN_Sv,HLES_AVG)

CALL LES_DIACHRO_MASKS("MEANWIND",YSUBTITLE(:), &
  "Profile of Mean Modulus of Wind"//YSUBTITLE(:)," m/s",XLES_MEAN_WIND,HLES_AVG)
!
CALL LES_DIACHRO_MASKS("MEANMSFX",YSUBTITLE(:),  &
     "Total updraft mass flux"//YSUBTITLE(:)," kg/m2/s",XLES_RESOLVED_MASSFX   ,HLES_AVG)
!
IF (LLES_PDF) THEN
  CALL LES_DIACHRO_SV_MASKS("PDF_TH ",YSUBTITLE(:), &
  "Pdf potential temperature Profiles"//YSUBTITLE(:)," ",XLES_PDF_TH,HLES_AVG)
  CALL LES_DIACHRO_SV_MASKS("PDF_W ",YSUBTITLE(:), &
  "Pdf vertical velocity Profiles"//YSUBTITLE(:)," ",XLES_PDF_W,HLES_AVG)
  CALL LES_DIACHRO_SV_MASKS("PDF_THV ",YSUBTITLE(:), &
  "Pdf virtual pot. temp. Profiles"//YSUBTITLE(:)," ",XLES_PDF_THV,HLES_AVG)
    
  IF (LUSERV) THEN
   CALL LES_DIACHRO_SV_MASKS("PDF_RV ",YSUBTITLE(:), &
     "Pdf Rv Profiles"//YSUBTITLE(:)," ",XLES_PDF_RV,HLES_AVG)
  END IF

  IF (LUSERC) THEN
   CALL LES_DIACHRO_SV_MASKS("PDF_RC ",YSUBTITLE(:), &
   "Pdf Rc Profiles"//YSUBTITLE(:)," ",XLES_PDF_RC,HLES_AVG)

   CALL LES_DIACHRO_SV_MASKS("PDF_RT ",YSUBTITLE(:), &
   "Pdf Rt Profiles"//YSUBTITLE(:)," ",XLES_PDF_RT,HLES_AVG)

   CALL LES_DIACHRO_SV_MASKS("PDF_THL ",YSUBTITLE(:), &
   "Pdf Thl Profiles"//YSUBTITLE(:)," ",XLES_PDF_THL,HLES_AVG)
  END IF
  IF (LUSERR) &
  CALL LES_DIACHRO_SV_MASKS("PDF_RR ",YSUBTITLE(:), &
  "Pdf Rr Profiles"//YSUBTITLE(:)," ",XLES_PDF_RR,HLES_AVG)

  IF (LUSERI) &
  CALL LES_DIACHRO_SV_MASKS("PDF_RI ",YSUBTITLE(:), &
  "Pdf Ri Profiles"//YSUBTITLE(:)," ",XLES_PDF_RI,HLES_AVG)

  IF (LUSERS) &
  CALL LES_DIACHRO_SV_MASKS("PDF_RS ",YSUBTITLE(:), &
  "Pdf Rs Profiles"//YSUBTITLE(:)," ",XLES_PDF_RS,HLES_AVG)

  IF (LUSERG) &
  CALL LES_DIACHRO_SV_MASKS("PDF_RG ",YSUBTITLE(:), &
  "Pdf Rg Profiles"//YSUBTITLE(:)," ",XLES_PDF_RG,HLES_AVG)

END IF
!
!*      2.2  resolved quantities
!            -------------------
!
IF (LLES_RESOLVED) THEN
  CALL LES_DIACHRO_MASKS("RES_U2  ",YSUBTITLE(:), &
     "Resolved <u2> variance "//YSUBTITLE(:),"m2/s2",XLES_RESOLVED_U2,HLES_AVG)

  CALL LES_DIACHRO_MASKS("RES_V2  ",YSUBTITLE(:), &
     "Resolved <v2> variance"//YSUBTITLE(:),"m2/s2",XLES_RESOLVED_V2,HLES_AVG)

  CALL LES_DIACHRO_MASKS("RES_W2  ",YSUBTITLE(:), &
     "Resolved <w2> variance"//YSUBTITLE(:),"m2/s2",XLES_RESOLVED_W2,HLES_AVG)

  CALL LES_DIACHRO_MASKS("RES_UV  ",YSUBTITLE(:), &
     "Resolved <uv> Flux"//YSUBTITLE(:),"m2/s2",XLES_RESOLVED_UV,HLES_AVG)

  CALL LES_DIACHRO_MASKS("RES_WU  ",YSUBTITLE(:), &
   "Resolved <wu> Flux"//YSUBTITLE(:),"m2/s2",XLES_RESOLVED_WU,HLES_AVG)

  CALL LES_DIACHRO_MASKS("RES_WV  ",YSUBTITLE(:), &
     "Resolved <wv> Flux"//YSUBTITLE(:),"m2/s2",XLES_RESOLVED_WV,HLES_AVG)

  CALL LES_DIACHRO_MASKS("RES_KE  ",YSUBTITLE(:), &
     "Resolved TKE Profile"//YSUBTITLE(:),"m2/s2",XLES_RESOLVED_Ke,HLES_AVG)

  CALL LES_DIACHRO_MASKS("RES_P2  ",YSUBTITLE(:), &
     "Resolved pressure variance"//YSUBTITLE(:),"Pa2",XLES_RESOLVED_P2,HLES_AVG)

  CALL LES_DIACHRO_MASKS("RES_UPZ ",YSUBTITLE(:), &
     "Resolved <up> horizontal Flux"//YSUBTITLE(:),"Pa/s",XLES_RESOLVED_UP,HLES_AVG)

  CALL LES_DIACHRO_MASKS("RES_VPZ ",YSUBTITLE(:), &
     "Resolved <vp> horizontal Flux"//YSUBTITLE(:),"Pa/s",XLES_RESOLVED_VP,HLES_AVG)

  CALL LES_DIACHRO_MASKS("RES_WPZ ",YSUBTITLE(:), &
     "Resolved <wp> vertical Flux"//YSUBTITLE(:),"Pa/s",XLES_RESOLVED_WP,HLES_AVG)

  IF (LUSERV) &
  CALL LES_DIACHRO_MASKS("RES_THTV ",YSUBTITLE(:), &
     "Resolved potential temperature - virtual potential temperature covariance"//YSUBTITLE(:), &
     "K2",XLES_RESOLVED_ThThv,HLES_AVG)

  IF (LUSERC) &
  CALL LES_DIACHRO_MASKS("RES_TLTV ",YSUBTITLE(:), &
     "Resolved liquid potential temperature - virtual potential temperature covariance"//YSUBTITLE(:), &
     "K2",XLES_RESOLVED_ThlThv,HLES_AVG)

  CALL LES_DIACHRO_MASKS("RES_TH2 ",YSUBTITLE(:), &
     "Resolved potential temperature variance"//YSUBTITLE(:),"K2",XLES_RESOLVED_Th2,HLES_AVG)

  IF (LUSERC) &
  CALL LES_DIACHRO_MASKS("RES_THL2",YSUBTITLE(:), &
     "Resolved liquid potential temperature variance"//YSUBTITLE(:),"K2",XLES_RESOLVED_Thl2,HLES_AVG)

  CALL LES_DIACHRO_MASKS("RES_UTH ",YSUBTITLE(:), &
     "Resolved <uth> horizontal Flux"//YSUBTITLE(:),"mK/s",XLES_RESOLVED_UTh,HLES_AVG)

  CALL LES_DIACHRO_MASKS("RES_VTH ",YSUBTITLE(:), &
     "Resolved <vth> horizontal Flux"//YSUBTITLE(:),"mK/s",XLES_RESOLVED_VTh,HLES_AVG)

  CALL LES_DIACHRO_MASKS("RES_WTH ",YSUBTITLE(:), &
     "Resolved <wth> vertical Flux"//YSUBTITLE(:),"mK/s",XLES_RESOLVED_WTh,HLES_AVG)

  IF (LUSERC) THEN
    CALL LES_DIACHRO_MASKS("RES_UTHL",YSUBTITLE(:), &
       "Resolved <uthl> horizontal Flux"//YSUBTITLE(:),"mK/s",XLES_RESOLVED_UThl,HLES_AVG)

    CALL LES_DIACHRO_MASKS("RES_VTHL",YSUBTITLE(:), &
       "Resolved <vthl> horizontal Flux"//YSUBTITLE(:),"mK/s",XLES_RESOLVED_VThl,HLES_AVG)

    CALL LES_DIACHRO_MASKS("RES_WTHL",YSUBTITLE(:), &
       "Resolved <wthl> vertical Flux "//YSUBTITLE(:),"mK/s",XLES_RESOLVED_WThl,HLES_AVG)

    CALL LES_DIACHRO_MASKS("RES_RT2 ",YSUBTITLE(:), &
     "Resolved total water variance"//YSUBTITLE(:),"kg2/kg2",XLES_RESOLVED_Rt2,HLES_AVG)

    CALL LES_DIACHRO_MASKS("RES_WRT ",YSUBTITLE(:), &
       "Resolved <wrt> vertical Flux "//YSUBTITLE(:),"mkg/kg/s",XLES_RESOLVED_WRt,HLES_AVG)
  END IF

  IF (LUSERV) THEN

    CALL LES_DIACHRO_MASKS("RES_UTHV",YSUBTITLE(:), &
       "Resolved <uthv> horizontal Flux"//YSUBTITLE(:),"mK/s",XLES_RESOLVED_UThv,HLES_AVG)

    CALL LES_DIACHRO_MASKS("RES_VTHV",YSUBTITLE(:), &
       "Resolved <vthl> horizontal Flux"//YSUBTITLE(:),"mK/s",XLES_RESOLVED_VThv,HLES_AVG)

    CALL LES_DIACHRO_MASKS("RES_WTHV",YSUBTITLE(:), &
       "Resolved <wthv> vertical Flux "//YSUBTITLE(:),"mK/s",XLES_RESOLVED_WThv,HLES_AVG)
  END IF
!
  IF (LUSERV) THEN
    CALL LES_DIACHRO_MASKS("RES_RV2 ",YSUBTITLE(:), &
       "Resolved water vapor variance"//YSUBTITLE(:),"kg2/kg2",XLES_RESOLVED_Rv2,HLES_AVG)

    CALL LES_DIACHRO_MASKS("RES_THRV",YSUBTITLE(:), &
       "Resolved <thrv> covariance"//YSUBTITLE(:),"Kkg/kg",XLES_RESOLVED_ThRv,HLES_AVG)

    IF (LUSERC) &
    CALL LES_DIACHRO_MASKS("RES_TLRV",YSUBTITLE(:), &
       "Resolved <thlrv> covariance"//YSUBTITLE(:),"Kkg/kg",XLES_RESOLVED_ThlRv,HLES_AVG)

    CALL LES_DIACHRO_MASKS("RES_TVRV",YSUBTITLE(:), &
       "Resolved <thvrv> covariance"//YSUBTITLE(:),"Kkg/kg",XLES_RESOLVED_ThvRv,HLES_AVG)

    CALL LES_DIACHRO_MASKS("RES_URV ", YSUBTITLE(:), &
       "Resolved <urv> horizontal flux"//YSUBTITLE(:),"mkg/kg/s",XLES_RESOLVED_URv,HLES_AVG)

    CALL LES_DIACHRO_MASKS("RES_VRV ", YSUBTITLE(:), &
       "Resolved <vrv> horizontal flux"//YSUBTITLE(:),"mkg/kg/s",XLES_RESOLVED_VRv,HLES_AVG)

    CALL LES_DIACHRO_MASKS("RES_WRV ", YSUBTITLE(:), &
       "Resolved <wrv> vertical flux"//YSUBTITLE(:),"mkg/kg/s",XLES_RESOLVED_WRv,HLES_AVG)
  END IF

  IF (LUSERC) THEN
    CALL LES_DIACHRO_MASKS("RES_RC2 ", YSUBTITLE(:), &
       "Resolved cloud water variance"//YSUBTITLE(:),"kg2/kg2",XLES_RESOLVED_Rc2,HLES_AVG)

    CALL LES_DIACHRO_MASKS("RES_THRC", YSUBTITLE(:), &
       "Resolved <thrc> covariance"//YSUBTITLE(:),"Kkg/kg",XLES_RESOLVED_ThRc,HLES_AVG)

    CALL LES_DIACHRO_MASKS("RES_TLRC", YSUBTITLE(:), &
       "Resolved <thlrc> covariance"//YSUBTITLE(:),"Kkg/kg",XLES_RESOLVED_ThlRc,HLES_AVG)

    CALL LES_DIACHRO_MASKS("RES_TVRC", YSUBTITLE(:), &
       "Resolved <thvrc> covariance"//YSUBTITLE(:),"Kkg/kg",XLES_RESOLVED_ThvRc,HLES_AVG)

    CALL LES_DIACHRO_MASKS("RES_URC ", YSUBTITLE(:), &
       "Resolved <urc> horizontal flux"//YSUBTITLE(:),"mkg/kg/s",XLES_RESOLVED_URc,HLES_AVG)

    CALL LES_DIACHRO_MASKS("RES_VRC ", YSUBTITLE(:), &
       "Resolved <vrc> horizontal flux"//YSUBTITLE(:),"mkg/kg/s",XLES_RESOLVED_VRc,HLES_AVG)

    CALL LES_DIACHRO_MASKS("RES_WRC ", YSUBTITLE(:), &
       "Resolved <wrc> vertical flux"//YSUBTITLE(:),"mkg/kg/s",XLES_RESOLVED_WRc,HLES_AVG)
  END IF

  IF (LUSERI) THEN
    CALL LES_DIACHRO_MASKS("RES_RI2 ", YSUBTITLE(:), &
       "Resolved cloud ice variance"//YSUBTITLE(:),"kg2/kg2",XLES_RESOLVED_Ri2,HLES_AVG)

    CALL LES_DIACHRO_MASKS("RES_THRI", YSUBTITLE(:), &
       "Resolved <thri> covariance"//YSUBTITLE(:),"Kkg/kg",XLES_RESOLVED_ThRi,HLES_AVG)

    CALL LES_DIACHRO_MASKS("RES_TLRI", YSUBTITLE(:), &
       "Resolved <thlri> covariance"//YSUBTITLE(:),"Kkg/kg",XLES_RESOLVED_ThlRi,HLES_AVG)

    CALL LES_DIACHRO_MASKS("RES_TVRI", YSUBTITLE(:), &
       "Resolved <thvri> covariance"//YSUBTITLE(:),"Kkg/kg",XLES_RESOLVED_ThvRi,HLES_AVG)

    CALL LES_DIACHRO_MASKS("RES_URI ", YSUBTITLE(:), &
       "Resolved <uri> horizontal flux"//YSUBTITLE(:),"mkg/kg/s",XLES_RESOLVED_URi,HLES_AVG)

    CALL LES_DIACHRO_MASKS("RES_VRI ", YSUBTITLE(:), &
       "Resolved <vri> horizontal flux"//YSUBTITLE(:),"mkg/kg/s",XLES_RESOLVED_VRi,HLES_AVG)

    CALL LES_DIACHRO_MASKS("RES_WRI ", YSUBTITLE(:), &
       "Resolved <wri> vertical flux"//YSUBTITLE(:),"mkg/kg/s",XLES_RESOLVED_WRi,HLES_AVG)
  END IF

  IF (LUSERR) THEN
    CALL LES_DIACHRO_MASKS("RES_WRR ", YSUBTITLE(:), &
       "Resolved <wrr> vertical flux"//YSUBTITLE(:),"mkg/kg/s",XLES_RESOLVED_WRr,HLES_AVG)
    
    CALL LES_DIACHRO_MASKS("INPRR3D ", YSUBTITLE(:), &
       "Precipitation flux"//YSUBTITLE(:),"m/s",XLES_INPRR3D,HLES_AVG)   
        
    CALL LES_DIACHRO_MASKS("MAXINPR3D ", YSUBTITLE(:), &
       "Max Precip flux"//YSUBTITLE(:),"m/s",XLES_MAX_INPRR3D,HLES_AVG)   
        
    CALL LES_DIACHRO_MASKS("EVAP3D ", YSUBTITLE(:), &
       "Evaporation profile"//YSUBTITLE(:),"kg/kg/s",XLES_EVAP3D,HLES_AVG)
  ENDIF
  IF (NSV>0) THEN
    CALL LES_DIACHRO_SV_MASKS("RES_SV2 ", YSUBTITLE(:), &
       "Resolved scalar variables variances"//YSUBTITLE(:),"kg2/kg2",XLES_RESOLVED_Sv2,HLES_AVG)

    CALL LES_DIACHRO_SV_MASKS("RES_THSV", YSUBTITLE(:), &
       "Resolved <ThSv> variance"//YSUBTITLE(:),"Kkg/kg",XLES_RESOLVED_ThSv,HLES_AVG)

    IF (LUSERC) &
    CALL LES_DIACHRO_SV_MASKS("RES_TLSV", YSUBTITLE(:), &
       "Resolved <ThlSv> variance"//YSUBTITLE(:),"Kkg/kg",XLES_RESOLVED_ThlSv,HLES_AVG)

    IF (LUSERV) &
    CALL LES_DIACHRO_SV_MASKS("RES_TVSV", YSUBTITLE(:), &
       "Resolved <ThvSv> variance"//YSUBTITLE(:),"Kkg/kg",XLES_RESOLVED_ThvSv,HLES_AVG)

    CALL LES_DIACHRO_SV_MASKS("RES_USV ", YSUBTITLE(:), &
       "Resolved <uSv> horizontal flux"//YSUBTITLE(:),"mkg/kg/s",XLES_RESOLVED_USv,HLES_AVG)

    CALL LES_DIACHRO_SV_MASKS("RES_VSV ", YSUBTITLE(:), &
       "Resolved <vSv> horizontal flux"//YSUBTITLE(:),"mkg/kg/s",XLES_RESOLVED_VSv,HLES_AVG)

    CALL LES_DIACHRO_SV_MASKS("RES_WSV ", YSUBTITLE(:), &
       "Resolved <wSv> vertical flux"//YSUBTITLE(:),"mkg/kg/s",XLES_RESOLVED_WSv,HLES_AVG)
  END IF

  CALL LES_DIACHRO_MASKS("RES_U3  ",YSUBTITLE(:),  &
       "Resolved <w3>"//YSUBTITLE(:),"m3/s3",XLES_RESOLVED_U3,HLES_AVG)

  CALL LES_DIACHRO_MASKS("RES_V3  ",YSUBTITLE(:),  &
       "Resolved <w3>"//YSUBTITLE(:),"m3/s3",XLES_RESOLVED_V3,HLES_AVG)
    
  CALL LES_DIACHRO_MASKS("RES_W3  ",YSUBTITLE(:),  &
       "Resolved <w3>"//YSUBTITLE(:),"m3/s3",XLES_RESOLVED_W3,HLES_AVG)

  CALL LES_DIACHRO_MASKS("RES_U4  ",YSUBTITLE(:),  &
       "Resolved <w3>"//YSUBTITLE(:),"m4/s4",XLES_RESOLVED_U4,HLES_AVG)

  CALL LES_DIACHRO_MASKS("RES_V4  ",YSUBTITLE(:),  &
       "Resolved <w3>"//YSUBTITLE(:),"m4/s4",XLES_RESOLVED_V4,HLES_AVG)
    
  CALL LES_DIACHRO_MASKS("RES_W4  ",YSUBTITLE(:),  &
       "Resolved <w3>"//YSUBTITLE(:),"m4/s4",XLES_RESOLVED_W4,HLES_AVG)


  CALL LES_DIACHRO_MASKS("RES_WTL2",YSUBTITLE(:),  &
       "Resolved <wThl2>"//YSUBTITLE(:),"mK2/s",XLES_RESOLVED_WThl2,HLES_AVG)

  CALL LES_DIACHRO_MASKS("RES_W2TL",YSUBTITLE(:),  &
       "Resolved <w2Thl>"//YSUBTITLE(:),"m2K/s2",XLES_RESOLVED_W2Thl,HLES_AVG)

  IF (LUSERV) THEN
    CALL LES_DIACHRO_MASKS("RES_WRV2",YSUBTITLE(:),  &
         "Resolved <wRv2>"//YSUBTITLE(:),"mkg2/kg2/s",XLES_RESOLVED_WRv2,HLES_AVG)

    CALL LES_DIACHRO_MASKS("RES_W2RV",YSUBTITLE(:),  &
         "Resolved <w2Rv>"//YSUBTITLE(:),"m2kg/kg/s2",XLES_RESOLVED_W2Rv,HLES_AVG)
     
    CALL LES_DIACHRO_MASKS("RES_WRT2",YSUBTITLE(:),  &
         "Resolved <wRt2>"//YSUBTITLE(:),"mkg2/kg2/s",XLES_RESOLVED_WRt2,HLES_AVG)

    CALL LES_DIACHRO_MASKS("RES_W2RT",YSUBTITLE(:),  &
         "Resolved <w2Rt>"//YSUBTITLE(:),"m2kg/kg/s2",XLES_RESOLVED_W2Rt,HLES_AVG)

    CALL LES_DIACHRO_MASKS("RE_WTLRV",YSUBTITLE(:),  &
         "Resolved <wThlRv>"//YSUBTITLE(:),"mKkg/kg/s",XLES_RESOLVED_WThlRv,HLES_AVG)
   
    CALL LES_DIACHRO_MASKS("RE_WTLRT",YSUBTITLE(:),  &
         "Resolved <wThlRt>"//YSUBTITLE(:),"mKkg/kg/s",XLES_RESOLVED_WThlRt,HLES_AVG)  
  END IF

  IF (LUSERC) THEN
    CALL LES_DIACHRO_MASKS("RES_WRC2",YSUBTITLE(:),  &
         "Resolved <wRc2>"//YSUBTITLE(:),"mkg2/kg2/s",XLES_RESOLVED_WRc2,HLES_AVG)

    CALL LES_DIACHRO_MASKS("RES_W2RC",YSUBTITLE(:),  &
         "Resolved <w2Rc>"//YSUBTITLE(:),"m2kg/kg/s2",XLES_RESOLVED_W2Rc,HLES_AVG)

    CALL LES_DIACHRO_MASKS("RE_WTLRC",YSUBTITLE(:),  &
         "Resolved <wThlRc>"//YSUBTITLE(:),"mKkg/kg/s",XLES_RESOLVED_WThlRc,HLES_AVG)

    CALL LES_DIACHRO_MASKS("RE_WRVRC",YSUBTITLE(:),  &
         "Resolved <wRvRc>"//YSUBTITLE(:),"mkg2/kg2/s",XLES_RESOLVED_WRvRc,HLES_AVG)
  END IF

  IF (LUSERI) THEN
    CALL LES_DIACHRO_MASKS("RES_WRI2",YSUBTITLE(:),  &
         "Resolved <wRi2>"//YSUBTITLE(:),"mkg2/kg2/s",XLES_RESOLVED_WRi2,HLES_AVG)

    CALL LES_DIACHRO_MASKS("RES_W2RI",YSUBTITLE(:),  &
         "Resolved <w2Ri>"//YSUBTITLE(:),"m2kg/kg/s2",XLES_RESOLVED_W2Ri,HLES_AVG)

    CALL LES_DIACHRO_MASKS("RE_WTLRI",YSUBTITLE(:),  &
         "Resolved <wThlRi>"//YSUBTITLE(:),"mKkg/kg/s",XLES_RESOLVED_WThlRi,HLES_AVG)

    CALL LES_DIACHRO_MASKS("RE_WRVRI",YSUBTITLE(:),  &
         "Resolved <wRvRi>"//YSUBTITLE(:),"mkg2/kg2/s",XLES_RESOLVED_WRvRi,HLES_AVG)
  END IF

  IF (NSV>0) THEN
    CALL LES_DIACHRO_SV_MASKS("RES_WSV2",YSUBTITLE(:),  &
         "Resolved <wSv2>"//YSUBTITLE(:),"mkg2/kg2/s",XLES_RESOLVED_WSv2,HLES_AVG)

    CALL LES_DIACHRO_SV_MASKS("RES_W2SV",YSUBTITLE(:),  &
         "Resolved <w2Sv>"//YSUBTITLE(:),"m2kg/kg/s2",XLES_RESOLVED_W2Sv,HLES_AVG)

    CALL LES_DIACHRO_SV_MASKS("RE_WTLSV",YSUBTITLE(:),  &
         "Resolved <wThlSv>"//YSUBTITLE(:),"mKkg/kg/s",XLES_RESOLVED_WThlSv,HLES_AVG)

    CALL LES_DIACHRO_SV_MASKS("RE_WRVSV",YSUBTITLE(:),  &
         "Resolved <wRvSv>"//YSUBTITLE(:),"mkg2/kg2/s",XLES_RESOLVED_WRvSv,HLES_AVG)
  END IF

  CALL LES_DIACHRO_MASKS("RES_TLPZ",YSUBTITLE(:),  &
       "Resolved <Thldp/dz>"//YSUBTITLE(:),"KPa/m",XLES_RESOLVED_ThlPz,HLES_AVG)

  IF (LUSERV) &
  CALL LES_DIACHRO_MASKS("RES_RVPZ",YSUBTITLE(:),  &
       "Resolved <Rvdp/dz>"//YSUBTITLE(:),"kg2/kg2Pa/m",XLES_RESOLVED_RvPz,HLES_AVG)

  IF (LUSERC) &
  CALL LES_DIACHRO_MASKS("RES_RCPZ",YSUBTITLE(:),  &
       "Resolved <Rcdp/dz>"//YSUBTITLE(:),"kg2/kg2Pa/m",XLES_RESOLVED_RcPz,HLES_AVG)

  IF (LUSERI) &
  CALL LES_DIACHRO_MASKS("RES_RIPZ",YSUBTITLE(:),  &
       "Resolved <Ridp/dz>"//YSUBTITLE(:),"kg2/kg2Pa/m",XLES_RESOLVED_RiPz,HLES_AVG)

  IF (NSV>0) THEN
    CALL LES_DIACHRO_SV_MASKS("RES_SVPZ",YSUBTITLE(:),  &
         "Resolved <Svdp/dz>"//YSUBTITLE(:),"kg2/kg2Pa/m",XLES_RESOLVED_SvPz,HLES_AVG)
  END IF

  CALL LES_DIACHRO_MASKS("RES_UKE ", YSUBTITLE(:), &
       "Resolved flux of resolved kinetic energy"//YSUBTITLE(:),"m3/s3",XLES_RESOLVED_UKe,HLES_AVG)

  CALL LES_DIACHRO_MASKS("RES_VKE ", YSUBTITLE(:), &
       "Resolved flux of resolved kinetic energy"//YSUBTITLE(:),"m3/s3",XLES_RESOLVED_VKe,HLES_AVG)

  CALL LES_DIACHRO_MASKS("RES_WKE ", YSUBTITLE(:), &
       "Resolved flux of resolved kinetic energy"//YSUBTITLE(:),"m3/s3",XLES_RESOLVED_WKe,HLES_AVG)

END IF
!
!
!*      2.3  subgrid quantities
!            ------------------
!
IF (LLES_SUBGRID) THEN

  CALL LES_DIACHRO_MASKS("SBG_TKE ",YSUBTITLE(:), &
       "Subgrid TKE"//YSUBTITLE(:),"m2/s2",XLES_SUBGRID_Tke,HLES_AVG)

  CALL LES_DIACHRO_MASKS("SBG_U2  ", YSUBTITLE(:), &
       "Subgrid <u2> variance"//YSUBTITLE(:),"m2/s2",XLES_SUBGRID_U2,HLES_AVG)

  CALL LES_DIACHRO_MASKS("SBG_V2  ", YSUBTITLE(:), &
       "Subgrid <v2> variance"//YSUBTITLE(:),"m2/s2",XLES_SUBGRID_V2,HLES_AVG)

  CALL LES_DIACHRO_MASKS("SBG_W2  ", YSUBTITLE(:), &
       "Subgrid <w2> variance"//YSUBTITLE(:),"m2/s2",XLES_SUBGRID_W2,HLES_AVG)

  CALL LES_DIACHRO_MASKS("SBG_UV  ", YSUBTITLE(:), &
       "Subgrid <uv> flux"//YSUBTITLE(:),"m2/s2",XLES_SUBGRID_UV,HLES_AVG)

  CALL LES_DIACHRO_MASKS("SBG_WU  ", YSUBTITLE(:), &
       "Subgrid <wu> flux"//YSUBTITLE(:),"m2/s2",XLES_SUBGRID_WU,HLES_AVG)

  CALL LES_DIACHRO_MASKS("SBG_WV  ", YSUBTITLE(:), &
       "Subgrid <wv> flux"//YSUBTITLE(:),"m2/s2",XLES_SUBGRID_WV,HLES_AVG)

  CALL LES_DIACHRO_MASKS("SBG_THL2", YSUBTITLE(:), &
       "Subgrid liquid potential temperature variance"//YSUBTITLE(:),"K2",XLES_SUBGRID_Thl2,HLES_AVG)

  CALL LES_DIACHRO_MASKS("SBG_UTHL", YSUBTITLE(:), &
       "Subgrid hor. flux of liquid potential temperature"//YSUBTITLE(:),"mK/s",XLES_SUBGRID_UThl,HLES_AVG)

  CALL LES_DIACHRO_MASKS("SBG_VTHL", YSUBTITLE(:), &
       "Subgrid hor. flux of liquid potential temperature"//YSUBTITLE(:),"mK/s",XLES_SUBGRID_VThl,HLES_AVG)

  CALL LES_DIACHRO_MASKS("SBG_WTHL", YSUBTITLE(:), &
       "Subgrid vert. flux of liquid potential temperature"//YSUBTITLE(:),"mK/s",XLES_SUBGRID_WThl,HLES_AVG)

  CALL LES_DIACHRO_MASKS("SBG_WP  ",YSUBTITLE(:), &
     "Subgrid <wp> vertical Flux"//YSUBTITLE(:),"mPa/s",XLES_SUBGRID_WP,HLES_AVG)
!!
!!
  CALL LES_DIACHRO_MASKS("THLUP_MF",YSUBTITLE(:), &
     "Subgrid <thl> of updraft"//YSUBTITLE(:),"K",XLES_SUBGRID_THLUP_MF,HLES_AVG)
!     
  CALL LES_DIACHRO_MASKS("RTUP_MF ",YSUBTITLE(:), &
     "Subgrid <rt> of updraft"//YSUBTITLE(:),"kg/kg",XLES_SUBGRID_RTUP_MF,HLES_AVG)
!     
  CALL LES_DIACHRO_MASKS("RVUP_MF ",YSUBTITLE(:), &
     "Subgrid <rv> of updraft"//YSUBTITLE(:),"kg/kg",XLES_SUBGRID_RVUP_MF,HLES_AVG)
!     
  CALL LES_DIACHRO_MASKS("RCUP_MF ",YSUBTITLE(:), &
     "Subgrid <rc> of updraft"//YSUBTITLE(:),"kg/kg",XLES_SUBGRID_RCUP_MF,HLES_AVG) 
!     
  CALL LES_DIACHRO_MASKS("RIUP_MF ",YSUBTITLE(:), &
     "Subgrid <ri> of updraft"//YSUBTITLE(:),"kg/kg",XLES_SUBGRID_RIUP_MF,HLES_AVG) 
!     
  CALL LES_DIACHRO_MASKS("WUP_MF  ",YSUBTITLE(:), &
     "Subgrid <w> of updraft"//YSUBTITLE(:),"m/s",XLES_SUBGRID_WUP_MF,HLES_AVG)  
!     
  CALL LES_DIACHRO_MASKS("MAFLX_MF",YSUBTITLE(:), &
     "Subgrid <MF> of updraft"//YSUBTITLE(:),"kg/m2/s",XLES_SUBGRID_MASSFLUX,HLES_AVG) 
!     
  CALL LES_DIACHRO_MASKS("DETR_MF ",YSUBTITLE(:), &
     "Subgrid <detr> of updraft"//YSUBTITLE(:),"kg/m3/s",XLES_SUBGRID_DETR,HLES_AVG) 
!     
  CALL LES_DIACHRO_MASKS("ENTR_MF ",YSUBTITLE(:), &
     "Subgrid <entr> of updraft"//YSUBTITLE(:),"kg/m3/s",XLES_SUBGRID_ENTR,HLES_AVG)  
!     
  CALL LES_DIACHRO_MASKS("FRCUP_MF",YSUBTITLE(:), &
     "Subgrid <FracUp> of updraft"//YSUBTITLE(:),"-",XLES_SUBGRID_FRACUP,HLES_AVG)   
!     
  CALL LES_DIACHRO_MASKS("THVUP_MF",YSUBTITLE(:), &
     "Subgrid <thv> of updraft"//YSUBTITLE(:),"K",&
                                XLES_SUBGRID_THVUP_MF,HLES_AVG) 
!     
  CALL LES_DIACHRO_MASKS("WTHL_MF ",YSUBTITLE(:), &
     "Subgrid <wthl> of mass flux convection scheme"//YSUBTITLE(:),"mk/s",&
                                XLES_SUBGRID_WTHLMF,HLES_AVG)  
!     
  CALL LES_DIACHRO_MASKS("WRT_MF  ",YSUBTITLE(:), &
     "Subgrid <wrt> of mass flux convection scheme"//YSUBTITLE(:),"mkg/kg/s",&
                                XLES_SUBGRID_WRTMF,HLES_AVG)   
!     
  CALL LES_DIACHRO_MASKS("WTHV_MF ",YSUBTITLE(:), &
     "Subgrid <wthv> of mass flux convection scheme"//YSUBTITLE(:),"mK/s",&
                                XLES_SUBGRID_WTHVMF,HLES_AVG)  
!     
  CALL LES_DIACHRO_MASKS("WU_MF   ",YSUBTITLE(:), &
     "Subgrid <wu> of mass flux convection scheme"//YSUBTITLE(:),"m2/s2",&
                                XLES_SUBGRID_WUMF,HLES_AVG)   
!     
  CALL LES_DIACHRO_MASKS("WV_MF   ",YSUBTITLE(:), &
     "Subgrid <wv> of mass flux convection scheme"//YSUBTITLE(:),"m2/s2",&
                                XLES_SUBGRID_WVMF,HLES_AVG)   
!!     

  CALL LES_DIACHRO_MASKS("SBG_PHI3",YSUBTITLE(:), &
     "Subgrid Phi3 function"//YSUBTITLE(:),"-",XLES_SUBGRID_PHI3,HLES_AVG)

  CALL LES_DIACHRO_MASKS("SBG_LMIX",YSUBTITLE(:), &
     "Subgrid Mixing Length"//YSUBTITLE(:),"-",XLES_SUBGRID_LMix,HLES_AVG)

  CALL LES_DIACHRO_MASKS("SBG_LDIS",YSUBTITLE(:), &
     "Subgrid Dissipation Length"//YSUBTITLE(:),"-",XLES_SUBGRID_LDiss,HLES_AVG)

  CALL LES_DIACHRO_MASKS("SBG_KM  ",YSUBTITLE(:), &
     "Eddy diffusivity for momentum"//YSUBTITLE(:),"m2/s",XLES_SUBGRID_Km,HLES_AVG)

  CALL LES_DIACHRO_MASKS("SBG_KH  ",YSUBTITLE(:), &
     "Eddy diffusivity for heat"//YSUBTITLE(:),"m2/s",XLES_SUBGRID_Kh,HLES_AVG)
!
  IF (LUSERV) THEN
     CALL LES_DIACHRO_MASKS("SBG_WTHV", YSUBTITLE(:), &
       "Subgrid vert. flux of liquid potential temperature"//YSUBTITLE(:),"mK/s",XLES_SUBGRID_WThv,HLES_AVG)
    CALL LES_DIACHRO_MASKS("SBG_RT2 ", YSUBTITLE(:), &
       "Subgrid total water variance"//YSUBTITLE(:),"kg2/kg2",XLES_SUBGRID_Rt2,HLES_AVG)

    CALL LES_DIACHRO_MASKS("SBG_TLRT", YSUBTITLE(:), &
       "Subgrid <thlrt> covariance"//YSUBTITLE(:),"Kkg/kg",XLES_SUBGRID_ThlRt,HLES_AVG)

    CALL LES_DIACHRO_MASKS("SBG_URT ", YSUBTITLE(:), &
       "Subgrid total water horizontal flux"//YSUBTITLE(:),"mkg/kg/s",XLES_SUBGRID_URt,HLES_AVG)

    CALL LES_DIACHRO_MASKS("SBG_VRT ", YSUBTITLE(:), &
       "Subgrid total water horizontal flux"//YSUBTITLE(:),"mkg/kg/s",XLES_SUBGRID_VRt,HLES_AVG)

    CALL LES_DIACHRO_MASKS("SBG_WRT ", YSUBTITLE(:), &
       "Subgrid total water vertical flux"//YSUBTITLE(:),"mkg/kg/s",XLES_SUBGRID_WRt,HLES_AVG)

    CALL LES_DIACHRO_MASKS("SBG_PSI3",YSUBTITLE(:), &
       "Subgrid Psi3 function"//YSUBTITLE(:),"-",XLES_SUBGRID_PSI3,HLES_AVG)  
  END IF

  IF (LUSERC) THEN
    CALL LES_DIACHRO_MASKS("SBG_RC2 ", YSUBTITLE(:), &
       "Subgrid cloud water variance"//YSUBTITLE(:),"kg2/kg2",XLES_SUBGRID_Rc2,HLES_AVG)

    CALL LES_DIACHRO_MASKS("SBG_URC ", YSUBTITLE(:), &
       "Subgrid cloud water horizontal flux"//YSUBTITLE(:),"mkg/kg/s",XLES_SUBGRID_URc,HLES_AVG)

    CALL LES_DIACHRO_MASKS("SBG_VRC ", YSUBTITLE(:), &
       "Subgrid cloud water horizontal flux"//YSUBTITLE(:),"mkg/kg/s",XLES_SUBGRID_VRc,HLES_AVG)

    CALL LES_DIACHRO_MASKS("SBG_WRC ", YSUBTITLE(:), &
       "Subgrid cloud water vertical flux"//YSUBTITLE(:),"mkg/kg/s",XLES_SUBGRID_WRc,HLES_AVG)
  END IF

  IF (NSV>0) THEN
    CALL LES_DIACHRO_SV_MASKS("SBG_USV ", YSUBTITLE(:), &
       "Subgrid <uSv> horizontal flux"//YSUBTITLE(:),"mkg/kg/s",XLES_SUBGRID_USv,HLES_AVG)

    CALL LES_DIACHRO_SV_MASKS("SBG_VSV ", YSUBTITLE(:), &
       "Subgrid <vSv> horizontal flux"//YSUBTITLE(:),"mkg/kg/s",XLES_SUBGRID_VSv,HLES_AVG)

    CALL LES_DIACHRO_SV_MASKS("SBG_WSV ", YSUBTITLE(:), &
       "Subgrid <wSv> vertical flux"//YSUBTITLE(:),"mkg/kg/s",XLES_SUBGRID_WSv,HLES_AVG)
  END IF

  CALL LES_DIACHRO_MASKS("SBG_UTKE", YSUBTITLE(:), &
     "Subgrid flux of subgrid kinetic energy"//YSUBTITLE(:),"m3/s3",XLES_SUBGRID_UTke,HLES_AVG)

  CALL LES_DIACHRO_MASKS("SBG_VTKE", YSUBTITLE(:), &
     "Subgrid flux of subgrid kinetic energy"//YSUBTITLE(:),"m3/s3",XLES_SUBGRID_VTke,HLES_AVG)

  CALL LES_DIACHRO_MASKS("SBG_WTKE",YSUBTITLE(:),  &
     "Subgrid flux of subgrid kinetic energy"//YSUBTITLE(:),"m3/s3",XLES_SUBGRID_WTke,HLES_AVG)
!
  CALL LES_DIACHRO_MASKS("SBG_W2TL",YSUBTITLE(:),  &
     "Subgrid flux of subgrid kinetic energy"//YSUBTITLE(:),"m2K/s2",XLES_SUBGRID_W2Thl,HLES_AVG)
!
  CALL LES_DIACHRO_MASKS("SBG_WTL2",YSUBTITLE(:),  &
     "Subgrid flux of subgrid kinetic energy"//YSUBTITLE(:),"mK2/s",XLES_SUBGRID_WThl2,HLES_AVG)
!
END IF
!
!*      2.4  Updraft quantities
!            ------------------
!
IF (LLES_UPDRAFT) THEN
  CALL LES_DIACHRO("UP_FRAC ",  &
       "Updraft fraction","-",XLES_UPDRAFT,HLES_AVG)

  CALL LES_DIACHRO("UP_W    ",  &
       "Updraft W mean value","m/s",XLES_UPDRAFT_W,HLES_AVG)

  CALL LES_DIACHRO("UP_TH   ",  &
       "Updraft potential temperature mean value","K",XLES_UPDRAFT_Th,HLES_AVG)

  IF (LUSERC) &
  CALL LES_DIACHRO("UP_THL  ",  &
       "Updraft liquid potential temperature mean value","K",XLES_UPDRAFT_Thl,HLES_AVG)

  IF (LUSERV) &
  CALL LES_DIACHRO("UP_THV  ",  &
       "Updraft virutal potential temperature mean value","K",XLES_UPDRAFT_Thv,HLES_AVG)

  CALL LES_DIACHRO("UP_KE   ",  &
       "Updraft resolved TKE mean value","m2/s2",XLES_UPDRAFT_Ke,HLES_AVG)

  CALL LES_DIACHRO("UP_TKE  ",  &
       "Updraft subgrid TKE mean value","m2/s2",XLES_UPDRAFT_Tke,HLES_AVG)

  IF (LUSERV) &
  CALL LES_DIACHRO("UP_RV   ",  &
       "Updraft water vapor mean value","kg/kg",XLES_UPDRAFT_Rv,HLES_AVG)

  IF (LUSERC) &
  CALL LES_DIACHRO("UP_RC   ",  &
       "Updraft cloud water mean value","kg/kg",XLES_UPDRAFT_Rc,HLES_AVG)

  IF (LUSERR) &
  CALL LES_DIACHRO("UP_RR   ",  &
       "Updraft rain mean value","kg/kg",XLES_UPDRAFT_Rr,HLES_AVG)

  IF (LUSERI) &
  CALL LES_DIACHRO("UP_RI   ",  &
       "Updraft ice mean value","kg/kg",XLES_UPDRAFT_Ri,HLES_AVG)

  IF (LUSERS) &
  CALL LES_DIACHRO("UP_RS   ",  &
       "Updraft snow mean value","kg/kg",XLES_UPDRAFT_Rs,HLES_AVG)

  IF (LUSERG) &
  CALL LES_DIACHRO("UP_RG   ",  &
       "Updraft graupel mean value","kg/kg",XLES_UPDRAFT_Rg,HLES_AVG)

  IF (LUSERH) &
  CALL LES_DIACHRO("UP_RH   ",  &
       "Updraft hail mean value","kg/kg",XLES_UPDRAFT_Rh,HLES_AVG)

  IF (NSV>0) &
  CALL LES_DIACHRO_SV("UP_SV   ",  &
       "Updraft scalar variables mean values","kg/kg",XLES_UPDRAFT_Sv,HLES_AVG)
  !
  CALL LES_DIACHRO("UP_TH2 ",  &
       "Updraft resolved Theta variance ","K2",XLES_UPDRAFT_Th2,HLES_AVG)

  IF (LUSERC) &
  CALL LES_DIACHRO("UP_THL2",  &
       "Updraft resolved Theta_l variance ","K2",XLES_UPDRAFT_Thl2,HLES_AVG)

  IF (LUSERV) &
  CALL LES_DIACHRO("UP_THTV",  &
       "Updraft resolved Theta Theta_v covariance ","K2",XLES_UPDRAFT_ThThv,HLES_AVG)