[3] | 1 | MODULE ldfdyn |
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| 2 | !!====================================================================== |
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| 3 | !! *** MODULE ldfdyn *** |
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| 4 | !! Ocean physics: lateral viscosity coefficient |
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| 5 | !!===================================================================== |
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[1601] | 6 | !! History : OPA ! 1997-07 (G. Madec) multi dimensional coefficients |
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| 7 | !! NEMO 1.0 ! 2002-09 (G. Madec) F90: Free form and module |
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[5836] | 8 | !! 3.7 ! 2014-01 (F. Lemarie, G. Madec) restructuration/simplification of ahm specification, |
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| 9 | !! ! add velocity dependent coefficient and optional read in file |
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[1601] | 10 | !!---------------------------------------------------------------------- |
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[3] | 11 | |
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| 12 | !!---------------------------------------------------------------------- |
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[5836] | 13 | !! ldf_dyn_init : initialization, namelist read, and parameters control |
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| 14 | !! ldf_dyn : update lateral eddy viscosity coefficients at each time step |
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[3] | 15 | !!---------------------------------------------------------------------- |
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| 16 | USE oce ! ocean dynamics and tracers |
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| 17 | USE dom_oce ! ocean space and time domain |
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| 18 | USE phycst ! physical constants |
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[5836] | 19 | USE ldfc1d_c2d ! lateral diffusion: 1D and 2D cases |
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| 20 | ! |
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[3] | 21 | USE in_out_manager ! I/O manager |
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[5836] | 22 | USE iom ! I/O module for ehanced bottom friction file |
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| 23 | USE timing ! Timing |
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[3] | 24 | USE lib_mpp ! distribued memory computing library |
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| 25 | USE lbclnk ! ocean lateral boundary conditions (or mpp link) |
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| 26 | |
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| 27 | IMPLICIT NONE |
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| 28 | PRIVATE |
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| 29 | |
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[5836] | 30 | PUBLIC ldf_dyn_init ! called by nemogcm.F90 |
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| 31 | PUBLIC ldf_dyn ! called by step.F90 |
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[3] | 32 | |
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[5836] | 33 | ! !!* Namelist namdyn_ldf : lateral mixing on momentum * |
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| 34 | LOGICAL , PUBLIC :: ln_dynldf_lap !: laplacian operator |
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| 35 | LOGICAL , PUBLIC :: ln_dynldf_blp !: bilaplacian operator |
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| 36 | LOGICAL , PUBLIC :: ln_dynldf_lev !: iso-level direction |
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| 37 | LOGICAL , PUBLIC :: ln_dynldf_hor !: horizontal (geopotential) direction |
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| 38 | LOGICAL , PUBLIC :: ln_dynldf_iso !: iso-neutral direction |
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| 39 | INTEGER , PUBLIC :: nn_ahm_ijk_t !: choice of time & space variations of the lateral eddy viscosity coef. |
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| 40 | REAL(wp), PUBLIC :: rn_ahm_0 !: lateral laplacian eddy viscosity [m2/s] |
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| 41 | REAL(wp), PUBLIC :: rn_ahm_b !: lateral laplacian background eddy viscosity [m2/s] |
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| 42 | REAL(wp), PUBLIC :: rn_bhm_0 !: lateral bilaplacian eddy viscosity [m4/s] |
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[7646] | 43 | !! If nn_ahm_ijk_t = 32 a time and space varying Smagorinsky viscosity |
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| 44 | !! will be computed. |
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| 45 | REAL(wp), PUBLIC :: rn_csmc !: Smagorinsky constant of proportionality |
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| 46 | REAL(wp), PUBLIC :: rn_minfac !: Multiplicative factor of theorectical minimum Smagorinsky viscosity |
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| 47 | REAL(wp), PUBLIC :: rn_maxfac !: Multiplicative factor of theorectical maximum Smagorinsky viscosity |
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[3] | 48 | |
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[5836] | 49 | LOGICAL , PUBLIC :: l_ldfdyn_time !: flag for time variation of the lateral eddy viscosity coef. |
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| 50 | |
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| 51 | REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:,:) :: ahmt, ahmf !: eddy diffusivity coef. at U- and V-points [m2/s or m4/s] |
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[7646] | 52 | REAL(wp), ALLOCATABLE, SAVE, DIMENSION(:,:) :: dtensq !: horizontal tension squared (Smagorinsky only) |
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| 53 | REAL(wp), ALLOCATABLE, SAVE, DIMENSION(:,:) :: dshesq !: horizontal shearing strain squared (Smagorinsky only) |
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| 54 | REAL(wp), ALLOCATABLE, SAVE, DIMENSION(:,:) :: esqt, esqf !: Square of the local gridscale (e1e2/(e1+e2))**2 |
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[5836] | 55 | |
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| 56 | REAL(wp) :: r1_12 = 1._wp / 12._wp ! =1/12 |
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| 57 | REAL(wp) :: r1_4 = 0.25_wp ! =1/4 |
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[7646] | 58 | REAL(wp) :: r1_8 = 0.125_wp ! =1/8 |
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[5836] | 59 | REAL(wp) :: r1_288 = 1._wp / 288._wp ! =1/( 12^2 * 2 ) |
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| 60 | |
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[3] | 61 | !! * Substitutions |
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[5836] | 62 | # include "vectopt_loop_substitute.h90" |
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[3] | 63 | !!---------------------------------------------------------------------- |
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[5836] | 64 | !! NEMO/OPA 3.7 , NEMO Consortium (2014) |
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[1152] | 65 | !! $Id$ |
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[2715] | 66 | !! Software governed by the CeCILL licence (NEMOGCM/NEMO_CeCILL.txt) |
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[3] | 67 | !!---------------------------------------------------------------------- |
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| 68 | CONTAINS |
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| 69 | |
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| 70 | SUBROUTINE ldf_dyn_init |
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| 71 | !!---------------------------------------------------------------------- |
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| 72 | !! *** ROUTINE ldf_dyn_init *** |
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| 73 | !! |
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| 74 | !! ** Purpose : set the horizontal ocean dynamics physics |
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| 75 | !! |
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[5836] | 76 | !! ** Method : the eddy viscosity coef. specification depends on: |
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| 77 | !! - the operator: |
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| 78 | !! ln_dynldf_lap = T laplacian operator |
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| 79 | !! ln_dynldf_blp = T bilaplacian operator |
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| 80 | !! - the parameter nn_ahm_ijk_t: |
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| 81 | !! nn_ahm_ijk_t = 0 => = constant |
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| 82 | !! = 10 => = F(z) : = constant with a reduction of 1/4 with depth |
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| 83 | !! =-20 => = F(i,j) = shape read in 'eddy_viscosity.nc' file |
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| 84 | !! = 20 = F(i,j) = F(e1,e2) or F(e1^3,e2^3) (lap or bilap case) |
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| 85 | !! =-30 => = F(i,j,k) = shape read in 'eddy_viscosity.nc' file |
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| 86 | !! = 30 = F(i,j,k) = 2D (case 20) + decrease with depth (case 10) |
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| 87 | !! = 31 = F(i,j,k,t) = F(local velocity) ( |u|e /12 laplacian operator |
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| 88 | !! or |u|e^3/12 bilaplacian operator ) |
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[7646] | 89 | !! = 32 = F(i,j,k,t) = F(local deformation rate and gridscale) (D and L) (Smagorinsky) |
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| 90 | !! ( L^2|D| laplacian operator |
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| 91 | !! or L^4|D|/8 bilaplacian operator ) |
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[3] | 92 | !!---------------------------------------------------------------------- |
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[7646] | 93 | INTEGER :: ji, jj, jk ! dummy loop indices |
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[5836] | 94 | INTEGER :: ierr, inum, ios ! local integer |
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| 95 | REAL(wp) :: zah0 ! local scalar |
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| 96 | ! |
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| 97 | NAMELIST/namdyn_ldf/ ln_dynldf_lap, ln_dynldf_blp, & |
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| 98 | & ln_dynldf_lev, ln_dynldf_hor, ln_dynldf_iso, & |
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[7646] | 99 | & nn_ahm_ijk_t , rn_ahm_0, rn_ahm_b, rn_bhm_0, & |
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| 100 | & rn_csmc , rn_minfac, rn_maxfac |
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[5836] | 101 | !!---------------------------------------------------------------------- |
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| 102 | ! |
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[4147] | 103 | REWIND( numnam_ref ) ! Namelist namdyn_ldf in reference namelist : Lateral physics |
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| 104 | READ ( numnam_ref, namdyn_ldf, IOSTAT = ios, ERR = 901) |
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| 105 | 901 IF( ios /= 0 ) CALL ctl_nam ( ios , 'namdyn_ldf in reference namelist', lwp ) |
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[3] | 106 | |
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[4147] | 107 | REWIND( numnam_cfg ) ! Namelist namdyn_ldf in configuration namelist : Lateral physics |
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| 108 | READ ( numnam_cfg, namdyn_ldf, IOSTAT = ios, ERR = 902 ) |
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| 109 | 902 IF( ios /= 0 ) CALL ctl_nam ( ios , 'namdyn_ldf in configuration namelist', lwp ) |
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[4624] | 110 | IF(lwm) WRITE ( numond, namdyn_ldf ) |
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[4147] | 111 | |
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[1601] | 112 | IF(lwp) THEN ! Parameter print |
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[3] | 113 | WRITE(numout,*) |
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| 114 | WRITE(numout,*) 'ldf_dyn : lateral momentum physics' |
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| 115 | WRITE(numout,*) '~~~~~~~' |
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[4147] | 116 | WRITE(numout,*) ' Namelist namdyn_ldf : set lateral mixing parameters' |
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[5836] | 117 | ! |
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| 118 | WRITE(numout,*) ' type :' |
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| 119 | WRITE(numout,*) ' laplacian operator ln_dynldf_lap = ', ln_dynldf_lap |
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| 120 | WRITE(numout,*) ' bilaplacian operator ln_dynldf_blp = ', ln_dynldf_blp |
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| 121 | ! |
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| 122 | WRITE(numout,*) ' direction of action :' |
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| 123 | WRITE(numout,*) ' iso-level ln_dynldf_lev = ', ln_dynldf_lev |
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| 124 | WRITE(numout,*) ' horizontal (geopotential) ln_dynldf_hor = ', ln_dynldf_hor |
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| 125 | WRITE(numout,*) ' iso-neutral ln_dynldf_iso = ', ln_dynldf_iso |
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| 126 | ! |
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| 127 | WRITE(numout,*) ' coefficients :' |
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| 128 | WRITE(numout,*) ' type of time-space variation nn_ahm_ijk_t = ', nn_ahm_ijk_t |
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[7646] | 129 | WRITE(numout,*) ' lateral laplacian eddy viscosity rn_ahm_0 = ', rn_ahm_0, ' m2/s' |
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[5836] | 130 | WRITE(numout,*) ' background viscosity (iso case) rn_ahm_b = ', rn_ahm_b, ' m2/s' |
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[7646] | 131 | WRITE(numout,*) ' lateral bilaplacian eddy viscosity rn_bhm_0 = ', rn_bhm_0, ' m4/s' |
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| 132 | WRITE(numout,*) ' smagorinsky settings (nn_ahm_ijk_t = 32) :' |
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| 133 | WRITE(numout,*) ' Smagorinsky coefficient rn_csmc = ', rn_csmc |
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| 134 | WRITE(numout,*) ' factor multiplier for theorectical lower limit for ' |
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| 135 | WRITE(numout,*) ' Smagorinsky eddy visc (def. 1.0) rn_minfac = ', rn_minfac |
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| 136 | WRITE(numout,*) ' factor multiplier for theorectical lower upper for ' |
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| 137 | WRITE(numout,*) ' Smagorinsky eddy visc (def. 1.0) rn_maxfac = ', rn_maxfac |
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[3] | 138 | ENDIF |
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| 139 | |
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[5836] | 140 | ! ! Parameter control |
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| 141 | IF( .NOT.ln_dynldf_lap .AND. .NOT.ln_dynldf_blp ) THEN |
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| 142 | IF(lwp) WRITE(numout,*) ' No viscous operator selected. ahmt and ahmf are not allocated' |
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| 143 | l_ldfdyn_time = .FALSE. |
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| 144 | RETURN |
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[3] | 145 | ENDIF |
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[5836] | 146 | ! |
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| 147 | IF( ln_dynldf_blp .AND. ln_dynldf_iso ) THEN ! iso-neutral bilaplacian not implemented |
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| 148 | CALL ctl_stop( 'dyn_ldf_init: iso-neutral bilaplacian not coded yet' ) |
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[3] | 149 | ENDIF |
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| 150 | |
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[5836] | 151 | ! ... Space/Time variation of eddy coefficients |
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| 152 | ! ! allocate the ahm arrays |
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| 153 | ALLOCATE( ahmt(jpi,jpj,jpk) , ahmf(jpi,jpj,jpk) , STAT=ierr ) |
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| 154 | IF( ierr /= 0 ) CALL ctl_stop( 'STOP', 'ldf_dyn_init: failed to allocate arrays') |
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[1601] | 155 | ! |
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[7753] | 156 | ahmt(:,:,jpk) = 0._wp ! last level always 0 |
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| 157 | ahmf(:,:,jpk) = 0._wp |
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[5836] | 158 | ! |
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| 159 | ! ! value of eddy mixing coef. |
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| 160 | IF ( ln_dynldf_lap ) THEN ; zah0 = rn_ahm_0 ! laplacian operator |
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| 161 | ELSEIF( ln_dynldf_blp ) THEN ; zah0 = ABS( rn_bhm_0 ) ! bilaplacian operator |
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| 162 | ELSE ! NO viscous operator |
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| 163 | CALL ctl_warn( 'ldf_dyn_init: No lateral viscous operator used ' ) |
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[3] | 164 | ENDIF |
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[1601] | 165 | ! |
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[5836] | 166 | l_ldfdyn_time = .FALSE. ! no time variation except in case defined below |
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| 167 | ! |
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| 168 | IF( ln_dynldf_lap .OR. ln_dynldf_blp ) THEN ! only if a lateral diffusion operator is used |
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| 169 | ! |
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| 170 | SELECT CASE( nn_ahm_ijk_t ) ! Specification of space time variations of ahmt, ahmf |
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| 171 | ! |
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| 172 | CASE( 0 ) !== constant ==! |
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| 173 | IF(lwp) WRITE(numout,*) ' momentum mixing coef. = constant ' |
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[7753] | 174 | ahmt(:,:,:) = zah0 * tmask(:,:,:) |
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| 175 | ahmf(:,:,:) = zah0 * fmask(:,:,:) |
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[5836] | 176 | ! |
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| 177 | CASE( 10 ) !== fixed profile ==! |
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| 178 | IF(lwp) WRITE(numout,*) ' momentum mixing coef. = F( depth )' |
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[7753] | 179 | ahmt(:,:,1) = zah0 * tmask(:,:,1) ! constant surface value |
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| 180 | ahmf(:,:,1) = zah0 * fmask(:,:,1) |
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[5836] | 181 | CALL ldf_c1d( 'DYN', r1_4, ahmt(:,:,1), ahmf(:,:,1), ahmt, ahmf ) |
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| 182 | ! |
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| 183 | CASE ( -20 ) !== fixed horizontal shape read in file ==! |
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| 184 | IF(lwp) WRITE(numout,*) ' momentum mixing coef. = F(i,j) read in eddy_viscosity.nc file' |
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| 185 | CALL iom_open( 'eddy_viscosity_2D.nc', inum ) |
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| 186 | CALL iom_get ( inum, jpdom_data, 'ahmt_2d', ahmt(:,:,1) ) |
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| 187 | CALL iom_get ( inum, jpdom_data, 'ahmf_2d', ahmf(:,:,1) ) |
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| 188 | CALL iom_close( inum ) |
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| 189 | !!gm Question : info for LAP or BLP case to take into account the SQRT in the bilaplacian case ??? |
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| 190 | !! do we introduce a scaling by the max value of the array, and then multiply by zah0 ???? |
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| 191 | !! better: check that the max is <=1 i.e. it is a shape from 0 to 1, not a coef that has physical dimension |
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| 192 | DO jk = 2, jpkm1 |
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[7753] | 193 | ahmt(:,:,jk) = ahmt(:,:,1) * tmask(:,:,jk) |
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| 194 | ahmf(:,:,jk) = ahmf(:,:,1) * fmask(:,:,jk) |
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[5836] | 195 | END DO |
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| 196 | ! |
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| 197 | CASE( 20 ) !== fixed horizontal shape ==! |
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| 198 | IF(lwp) WRITE(numout,*) ' momentum mixing coef. = F( e1, e2 ) or F( e1^3, e2^3 ) (lap. or blp. case)' |
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| 199 | IF( ln_dynldf_lap ) CALL ldf_c2d( 'DYN', 'LAP', zah0, ahmt, ahmf ) ! surface value proportional to scale factor |
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| 200 | IF( ln_dynldf_blp ) CALL ldf_c2d( 'DYN', 'BLP', zah0, ahmt, ahmf ) ! surface value proportional to scale factor^3 |
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| 201 | ! |
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| 202 | CASE( -30 ) !== fixed 3D shape read in file ==! |
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| 203 | IF(lwp) WRITE(numout,*) ' momentum mixing coef. = F(i,j,k) read in eddy_diffusivity_3D.nc file' |
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| 204 | CALL iom_open( 'eddy_viscosity_3D.nc', inum ) |
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| 205 | CALL iom_get ( inum, jpdom_data, 'ahmt_3d', ahmt ) |
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| 206 | CALL iom_get ( inum, jpdom_data, 'ahmf_3d', ahmf ) |
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| 207 | CALL iom_close( inum ) |
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| 208 | !!gm Question : info for LAP or BLP case to take into account the SQRT in the bilaplacian case ???? |
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| 209 | !! do we introduce a scaling by the max value of the array, and then multiply by zah0 ???? |
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| 210 | DO jk = 1, jpkm1 |
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[7753] | 211 | ahmt(:,:,jk) = ahmt(:,:,jk) * tmask(:,:,jk) |
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| 212 | ahmf(:,:,jk) = ahmf(:,:,jk) * fmask(:,:,jk) |
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[5836] | 213 | END DO |
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| 214 | ! |
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| 215 | CASE( 30 ) !== fixed 3D shape ==! |
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| 216 | IF(lwp) WRITE(numout,*) ' momentum mixing coef. = F( latitude, longitude, depth )' |
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| 217 | IF( ln_dynldf_lap ) CALL ldf_c2d( 'DYN', 'LAP', zah0, ahmt, ahmf ) ! surface value proportional to scale factor |
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| 218 | IF( ln_dynldf_blp ) CALL ldf_c2d( 'DYN', 'BLP', zah0, ahmt, ahmf ) ! surface value proportional to scale factor |
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| 219 | ! ! reduction with depth |
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| 220 | CALL ldf_c1d( 'DYN', r1_4, ahmt(:,:,1), ahmf(:,:,1), ahmt, ahmf ) |
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| 221 | ! |
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| 222 | CASE( 31 ) !== time varying 3D field ==! |
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| 223 | IF(lwp) WRITE(numout,*) ' momentum mixing coef. = F( latitude, longitude, depth , time )' |
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| 224 | IF(lwp) WRITE(numout,*) ' proportional to the velocity : |u|e/12 or |u|e^3/12' |
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| 225 | ! |
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| 226 | l_ldfdyn_time = .TRUE. ! will be calculated by call to ldf_dyn routine in step.F90 |
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| 227 | ! |
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[7646] | 228 | CASE( 32 ) !== time varying 3D field ==! |
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| 229 | IF(lwp) WRITE(numout,*) ' momentum mixing coef. = F( latitude, longitude, depth , time )' |
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| 230 | IF(lwp) WRITE(numout,*) ' proportional to the local deformation rate and gridscale (Smagorinsky)' |
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| 231 | IF(lwp) WRITE(numout,*) ' : L^2|D| or L^4|D|/8' |
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| 232 | ! |
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| 233 | l_ldfdyn_time = .TRUE. ! will be calculated by call to ldf_dyn routine in step.F90 |
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| 234 | ! |
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| 235 | ! allocate arrays used in ldf_dyn. |
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| 236 | ALLOCATE( dtensq(jpi,jpj) , dshesq(jpi,jpj) , esqt(jpi,jpj) , esqf(jpi,jpj) , STAT=ierr ) |
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| 237 | IF( ierr /= 0 ) CALL ctl_stop( 'STOP', 'ldf_dyn_init: failed to allocate Smagorinsky arrays') |
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| 238 | ! |
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| 239 | ! Set local gridscale values |
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| 240 | DO jj = 2, jpjm1 |
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| 241 | DO ji = fs_2, fs_jpim1 |
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| 242 | esqt(ji,jj) = ( e1e2t(ji,jj) /( e1t(ji,jj) + e2t(ji,jj) ) )**2 |
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| 243 | esqf(ji,jj) = ( e1e2f(ji,jj) /( e1f(ji,jj) + e2f(ji,jj) ) )**2 |
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| 244 | END DO |
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| 245 | END DO |
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| 246 | ! |
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[5836] | 247 | CASE DEFAULT |
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| 248 | CALL ctl_stop('ldf_dyn_init: wrong choice for nn_ahm_ijk_t, the type of space-time variation of ahm') |
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| 249 | END SELECT |
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| 250 | ! |
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| 251 | IF( ln_dynldf_blp .AND. .NOT. l_ldfdyn_time ) THEN ! bilapcian and no time variation: |
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[7753] | 252 | ahmt(:,:,:) = SQRT( ahmt(:,:,:) ) ! take the square root of the coefficient |
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| 253 | ahmf(:,:,:) = SQRT( ahmf(:,:,:) ) |
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[5836] | 254 | ENDIF |
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| 255 | ! |
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[71] | 256 | ENDIF |
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[1601] | 257 | ! |
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[5836] | 258 | END SUBROUTINE ldf_dyn_init |
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[71] | 259 | |
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| 260 | |
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[5836] | 261 | SUBROUTINE ldf_dyn( kt ) |
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[3] | 262 | !!---------------------------------------------------------------------- |
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[5836] | 263 | !! *** ROUTINE ldf_dyn *** |
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| 264 | !! |
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| 265 | !! ** Purpose : update at kt the momentum lateral mixing coeff. (ahmt and ahmf) |
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[3] | 266 | !! |
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[5836] | 267 | !! ** Method : time varying eddy viscosity coefficients: |
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[3] | 268 | !! |
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[5836] | 269 | !! nn_ahm_ijk_t = 31 ahmt, ahmf = F(i,j,k,t) = F(local velocity) |
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| 270 | !! ( |u|e /12 or |u|e^3/12 for laplacian or bilaplacian operator ) |
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[3] | 271 | !! |
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[7646] | 272 | !! nn_ahm_ijk_t = 32 ahmt, ahmf = F(i,j,k,t) = F(local deformation rate and gridscale) (D and L) (Smagorinsky) |
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| 273 | !! ( L^2|D| or L^4|D|/8 for laplacian or bilaplacian operator ) |
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| 274 | !! |
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| 275 | !! ** note : in BLP cases the sqrt of the eddy coef is returned, since bilaplacian is en re-entrant laplacian |
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| 276 | !! ** action : ahmt, ahmf updated at each time step |
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[3] | 277 | !!---------------------------------------------------------------------- |
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[5836] | 278 | INTEGER, INTENT(in) :: kt ! time step index |
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[1601] | 279 | ! |
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[5836] | 280 | INTEGER :: ji, jj, jk ! dummy loop indices |
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| 281 | REAL(wp) :: zu2pv2_ij_p1, zu2pv2_ij, zu2pv2_ij_m1, zetmax, zefmax ! local scalar |
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[7646] | 282 | REAL(wp) :: zcmsmag, zstabf_lo, zstabf_up, zdelta, zdb ! local scalar |
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[5836] | 283 | !!---------------------------------------------------------------------- |
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| 284 | ! |
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| 285 | IF( nn_timing == 1 ) CALL timing_start('ldf_dyn') |
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| 286 | ! |
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| 287 | SELECT CASE( nn_ahm_ijk_t ) !== Eddy vicosity coefficients ==! |
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| 288 | ! |
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| 289 | CASE( 31 ) !== time varying 3D field ==! = F( local velocity ) |
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| 290 | ! |
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[7646] | 291 | IF( ln_dynldf_lap ) THEN ! laplacian operator : |u| e /12 = |u/144| e |
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[5836] | 292 | DO jk = 1, jpkm1 |
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| 293 | DO jj = 2, jpjm1 |
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| 294 | DO ji = fs_2, fs_jpim1 |
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| 295 | zu2pv2_ij_p1 = ub(ji ,jj+1,jk) * ub(ji ,jj+1,jk) + vb(ji+1,jj ,jk) * vb(ji+1,jj ,jk) |
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| 296 | zu2pv2_ij = ub(ji ,jj ,jk) * ub(ji ,jj ,jk) + vb(ji ,jj ,jk) * vb(ji ,jj ,jk) |
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| 297 | zu2pv2_ij_m1 = ub(ji-1,jj ,jk) * ub(ji-1,jj ,jk) + vb(ji ,jj-1,jk) * vb(ji ,jj-1,jk) |
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| 298 | zetmax = MAX( e1t(ji,jj) , e2t(ji,jj) ) |
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| 299 | zefmax = MAX( e1f(ji,jj) , e2f(ji,jj) ) |
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| 300 | ahmt(ji,jj,jk) = SQRT( (zu2pv2_ij + zu2pv2_ij_m1) * r1_288 ) * zetmax * tmask(ji,jj,jk) ! 288= 12*12 * 2 |
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| 301 | ahmf(ji,jj,jk) = SQRT( (zu2pv2_ij + zu2pv2_ij_p1) * r1_288 ) * zefmax * fmask(ji,jj,jk) |
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| 302 | END DO |
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| 303 | END DO |
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| 304 | END DO |
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| 305 | ELSEIF( ln_dynldf_blp ) THEN ! bilaplacian operator : sqrt( |u| e^3 /12 ) = sqrt( |u/144| e ) * e |
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| 306 | DO jk = 1, jpkm1 |
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| 307 | DO jj = 2, jpjm1 |
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| 308 | DO ji = fs_2, fs_jpim1 |
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| 309 | zu2pv2_ij_p1 = ub(ji ,jj+1,jk) * ub(ji ,jj+1,jk) + vb(ji+1,jj ,jk) * vb(ji+1,jj ,jk) |
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| 310 | zu2pv2_ij = ub(ji ,jj ,jk) * ub(ji ,jj ,jk) + vb(ji ,jj ,jk) * vb(ji ,jj ,jk) |
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| 311 | zu2pv2_ij_m1 = ub(ji-1,jj ,jk) * ub(ji-1,jj ,jk) + vb(ji ,jj-1,jk) * vb(ji ,jj-1,jk) |
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| 312 | zetmax = MAX( e1t(ji,jj) , e2t(ji,jj) ) |
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| 313 | zefmax = MAX( e1f(ji,jj) , e2f(ji,jj) ) |
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| 314 | ahmt(ji,jj,jk) = SQRT( SQRT( (zu2pv2_ij + zu2pv2_ij_m1) * r1_288 ) * zetmax ) * zetmax * tmask(ji,jj,jk) |
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| 315 | ahmf(ji,jj,jk) = SQRT( SQRT( (zu2pv2_ij + zu2pv2_ij_p1) * r1_288 ) * zefmax ) * zefmax * fmask(ji,jj,jk) |
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| 316 | END DO |
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| 317 | END DO |
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| 318 | END DO |
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| 319 | ENDIF |
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| 320 | ! |
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| 321 | CALL lbc_lnk( ahmt, 'T', 1. ) ; CALL lbc_lnk( ahmf, 'F', 1. ) |
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| 322 | ! |
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[7646] | 323 | ! |
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| 324 | CASE( 32 ) !== time varying 3D field ==! = F( local deformation rate and gridscale ) (Smagorinsky) |
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| 325 | ! |
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| 326 | IF( ln_dynldf_lap .OR. ln_dynldf_blp ) THEN ! laplacian operator : (C_smag/pi)^2 L^2 |D| |
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| 327 | ! |
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| 328 | zcmsmag = (rn_csmc/rpi)**2 ! (C_smag/pi)^2 |
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| 329 | zstabf_lo = rn_minfac * rn_minfac / ( 2._wp * 4._wp * zcmsmag ) ! lower limit stability factor scaling |
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| 330 | zstabf_up = rn_maxfac / ( 4._wp * zcmsmag * 2._wp * rdt ) ! upper limit stability factor scaling |
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| 331 | IF( ln_dynldf_blp ) zstabf_lo = ( 16._wp / 9._wp ) * zstabf_lo ! provide |U|L^3/12 lower limit instead |
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| 332 | ! ! of |U|L^3/16 in blp case |
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| 333 | DO jk = 1, jpkm1 |
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| 334 | ! |
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| 335 | DO jj = 2, jpj |
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| 336 | DO ji = 2, jpi |
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| 337 | zdb = ( ( ub(ji,jj,jk) * r1_e2u(ji,jj) - ub(ji-1,jj,jk) * r1_e2u(ji-1,jj) ) & |
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| 338 | & * r1_e1t(ji,jj) * e2t(ji,jj) & |
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| 339 | & - ( vb(ji,jj,jk) * r1_e1v(ji,jj) - vb(ji,jj-1,jk) * r1_e1v(ji,jj-1) ) & |
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| 340 | & * r1_e2t(ji,jj) * e1t(ji,jj) ) * tmask(ji,jj,jk) |
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| 341 | dtensq(ji,jj) = zdb*zdb |
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| 342 | END DO |
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| 343 | END DO |
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| 344 | ! |
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| 345 | DO jj = 1, jpjm1 |
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| 346 | DO ji = 1, jpim1 |
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| 347 | zdb = ( ( ub(ji,jj+1,jk) * r1_e1u(ji,jj+1) - ub(ji,jj,jk) * r1_e1u(ji,jj) ) & |
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| 348 | & * r1_e2f(ji,jj) * e1f(ji,jj) & |
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| 349 | & + ( vb(ji+1,jj,jk) * r1_e2v(ji+1,jj) - vb(ji,jj,jk) * r1_e2v(ji,jj) ) & |
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| 350 | & * r1_e1f(ji,jj) * e2f(ji,jj) ) * fmask(ji,jj,jk) |
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| 351 | dshesq(ji,jj) = zdb*zdb |
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| 352 | END DO |
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| 353 | END DO |
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| 354 | ! |
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| 355 | DO jj = 2, jpjm1 |
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| 356 | DO ji = fs_2, fs_jpim1 |
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| 357 | ! |
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| 358 | zu2pv2_ij_p1 = ub(ji ,jj+1,jk) * ub(ji ,jj+1,jk) + vb(ji+1,jj ,jk) * vb(ji+1,jj ,jk) |
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| 359 | zu2pv2_ij = ub(ji ,jj ,jk) * ub(ji ,jj ,jk) + vb(ji ,jj ,jk) * vb(ji ,jj ,jk) |
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| 360 | zu2pv2_ij_m1 = ub(ji-1,jj ,jk) * ub(ji-1,jj ,jk) + vb(ji ,jj-1,jk) * vb(ji ,jj-1,jk) |
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| 361 | ! T-point value |
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| 362 | zdelta = zcmsmag * esqt(ji,jj) ! L^2 * (C_smag/pi)^2 |
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| 363 | ahmt(ji,jj,jk) = zdelta * sqrt( dtensq(ji,jj) + & |
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| 364 | & r1_4 * ( dshesq(ji,jj) + dshesq(ji,jj-1) + & |
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| 365 | & dshesq(ji-1,jj) + dshesq(ji-1,jj-1) ) ) |
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| 366 | ahmt(ji,jj,jk) = MAX( ahmt(ji,jj,jk), & |
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| 367 | & SQRT( (zu2pv2_ij + zu2pv2_ij_m1) * zdelta * zstabf_lo ) ) ! Impose lower limit == minfac * |U|L/2 |
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| 368 | ahmt(ji,jj,jk) = MIN( ahmt(ji,jj,jk), zdelta * zstabf_up ) ! Impose upper limit == maxfac * L^2/(4*2dt) |
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| 369 | ! F-point value |
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| 370 | zdelta = zcmsmag * esqf(ji,jj) ! L^2 * (C_smag/pi)^2 |
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| 371 | ahmf(ji,jj,jk) = zdelta * sqrt( dshesq(ji,jj) + & |
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| 372 | & r1_4 * ( dtensq(ji,jj) + dtensq(ji,jj+1) + & |
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| 373 | & dtensq(ji+1,jj) + dtensq(ji+1,jj+1) ) ) |
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| 374 | ahmf(ji,jj,jk) = MAX( ahmf(ji,jj,jk), & |
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| 375 | & SQRT( (zu2pv2_ij + zu2pv2_ij_p1) * zdelta * zstabf_lo ) ) ! Impose lower limit == minfac * |U|L/2 |
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| 376 | ahmf(ji,jj,jk) = MIN( ahmf(ji,jj,jk), zdelta * zstabf_up ) ! Impose upper limit == maxfac * L^2/(4*2dt) |
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| 377 | ! |
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| 378 | END DO |
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| 379 | END DO |
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| 380 | END DO |
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| 381 | ! |
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| 382 | ENDIF |
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| 383 | ! |
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| 384 | IF( ln_dynldf_blp ) THEN ! bilaplacian operator : sqrt( (C_smag/pi)^2 L^4 |D|/8) |
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| 385 | ! = sqrt( A_lap_smag L^2/8 ) |
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| 386 | ! stability limits already applied to laplacian values |
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| 387 | ! effective default limits are |U|L^3/12 < B_hm < L^4/(32*2dt) |
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| 388 | ! |
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| 389 | DO jk = 1, jpkm1 |
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| 390 | ! |
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| 391 | DO jj = 2, jpjm1 |
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| 392 | DO ji = fs_2, fs_jpim1 |
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| 393 | ! |
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| 394 | ahmt(ji,jj,jk) = sqrt( r1_8 * esqt(ji,jj) * ahmt(ji,jj,jk) ) |
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| 395 | ahmf(ji,jj,jk) = sqrt( r1_8 * esqf(ji,jj) * ahmf(ji,jj,jk) ) |
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| 396 | ! |
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| 397 | END DO |
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| 398 | END DO |
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| 399 | END DO |
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| 400 | ! |
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| 401 | ENDIF |
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| 402 | ! |
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| 403 | CALL lbc_lnk( ahmt, 'T', 1. ) ; CALL lbc_lnk( ahmf, 'F', 1. ) |
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| 404 | ! |
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[5836] | 405 | END SELECT |
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| 406 | ! |
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| 407 | CALL iom_put( "ahmt_2d", ahmt(:,:,1) ) ! surface u-eddy diffusivity coeff. |
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| 408 | CALL iom_put( "ahmf_2d", ahmf(:,:,1) ) ! surface v-eddy diffusivity coeff. |
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| 409 | CALL iom_put( "ahmt_3d", ahmt(:,:,:) ) ! 3D u-eddy diffusivity coeff. |
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| 410 | CALL iom_put( "ahmf_3d", ahmf(:,:,:) ) ! 3D v-eddy diffusivity coeff. |
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| 411 | ! |
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| 412 | IF( nn_timing == 1 ) CALL timing_stop('ldf_dyn') |
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| 413 | ! |
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| 414 | END SUBROUTINE ldf_dyn |
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[3] | 415 | |
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| 416 | !!====================================================================== |
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| 417 | END MODULE ldfdyn |
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