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C $Header: /u/gcmpack/models/MITgcmUV/model/src/dynamics.F,v 1.38 1998/11/06 22:44:45 cnh Exp $ |
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|
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#include "CPP_OPTIONS.h" |
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|
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SUBROUTINE DYNAMICS(myTime, myIter, myThid) |
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C /==========================================================\ |
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C | SUBROUTINE DYNAMICS | |
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C | o Controlling routine for the explicit part of the model | |
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C | dynamics. | |
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C |==========================================================| |
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C | This routine evaluates the "dynamics" terms for each | |
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C | block of ocean in turn. Because the blocks of ocean have | |
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C | overlap regions they are independent of one another. | |
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C | If terms involving lateral integrals are needed in this | |
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C | routine care will be needed. Similarly finite-difference | |
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C | operations with stencils wider than the overlap region | |
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C | require special consideration. | |
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C | Notes | |
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C | ===== | |
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C | C*P* comments indicating place holders for which code is | |
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C | presently being developed. | |
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C \==========================================================/ |
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|
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C == Global variables === |
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#include "SIZE.h" |
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#include "EEPARAMS.h" |
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#include "CG2D.h" |
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#include "PARAMS.h" |
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#include "DYNVARS.h" |
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|
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C == Routine arguments == |
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C myTime - Current time in simulation |
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C myIter - Current iteration number in simulation |
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C myThid - Thread number for this instance of the routine. |
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INTEGER myThid |
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_RL myTime |
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INTEGER myIter |
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|
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C == Local variables |
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C xA, yA - Per block temporaries holding face areas |
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C uTrans, vTrans, rTrans - Per block temporaries holding flow |
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C transport |
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C rVel o uTrans: Zonal transport |
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C o vTrans: Meridional transport |
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C o rTrans: Vertical transport |
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C o rVel: Vertical velocity at upper and |
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C lower cell faces. |
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C maskC,maskUp o maskC: land/water mask for tracer cells |
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C o maskUp: land/water mask for W points |
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C aTerm, xTerm, cTerm - Work arrays for holding separate terms in |
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C mTerm, pTerm, tendency equations. |
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C fZon, fMer, fVer[STUV] o aTerm: Advection term |
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C o xTerm: Mixing term |
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C o cTerm: Coriolis term |
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C o mTerm: Metric term |
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C o pTerm: Pressure term |
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C o fZon: Zonal flux term |
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C o fMer: Meridional flux term |
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C o fVer: Vertical flux term - note fVer |
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C is "pipelined" in the vertical |
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C so we need an fVer for each |
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C variable. |
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C rhoK, rhoKM1 - Density at current level, level above and level |
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C below. |
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C rhoKP1 |
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C buoyK, buoyKM1 - Buoyancy at current level and level above. |
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C phiHyd - Hydrostatic part of the potential phiHydi. |
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C In z coords phiHydiHyd is the hydrostatic |
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C pressure anomaly |
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C In p coords phiHydiHyd is the geopotential |
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C surface height |
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C anomaly. |
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C etaSurfX, - Holds surface elevation gradient in X and Y. |
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C etaSurfY |
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C K13, K23, K33 - Non-zero elements of small-angle approximation |
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C diffusion tensor. |
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C KapGM - Spatially varying Visbeck et. al mixing coeff. |
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C KappaRT, - Total diffusion in vertical for T and S. |
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C KappaRS (background + spatially varying, isopycnal term). |
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C iMin, iMax - Ranges and sub-block indices on which calculations |
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C jMin, jMax are applied. |
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C bi, bj |
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C k, kUp, - Index for layer above and below. kUp and kDown |
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C kDown, kM1 are switched with layer to be the appropriate |
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C index into fVerTerm. |
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_RS xA (1-OLx:sNx+OLx,1-OLy:sNy+OLy) |
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_RS yA (1-OLx:sNx+OLx,1-OLy:sNy+OLy) |
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_RL uTrans (1-OLx:sNx+OLx,1-OLy:sNy+OLy) |
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_RL vTrans (1-OLx:sNx+OLx,1-OLy:sNy+OLy) |
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_RL rTrans (1-OLx:sNx+OLx,1-OLy:sNy+OLy) |
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_RL rVel (1-OLx:sNx+OLx,1-OLy:sNy+OLy,2) |
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_RS maskC (1-OLx:sNx+OLx,1-OLy:sNy+OLy) |
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_RS maskUp (1-OLx:sNx+OLx,1-OLy:sNy+OLy) |
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_RL aTerm (1-OLx:sNx+OLx,1-OLy:sNy+OLy) |
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_RL xTerm (1-OLx:sNx+OLx,1-OLy:sNy+OLy) |
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_RL cTerm (1-OLx:sNx+OLx,1-OLy:sNy+OLy) |
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_RL mTerm (1-OLx:sNx+OLx,1-OLy:sNy+OLy) |
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_RL pTerm (1-OLx:sNx+OLx,1-OLy:sNy+OLy) |
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_RL fZon (1-OLx:sNx+OLx,1-OLy:sNy+OLy) |
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_RL fMer (1-OLx:sNx+OLx,1-OLy:sNy+OLy) |
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_RL fVerT (1-OLx:sNx+OLx,1-OLy:sNy+OLy,2) |
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_RL fVerS (1-OLx:sNx+OLx,1-OLy:sNy+OLy,2) |
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_RL fVerU (1-OLx:sNx+OLx,1-OLy:sNy+OLy,2) |
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_RL fVerV (1-OLx:sNx+OLx,1-OLy:sNy+OLy,2) |
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_RL phiHyd (1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr) |
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_RL rhokm1 (1-OLx:sNx+OLx,1-OLy:sNy+OLy) |
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_RL rhokp1 (1-OLx:sNx+OLx,1-OLy:sNy+OLy) |
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_RL rhok (1-OLx:sNx+OLx,1-OLy:sNy+OLy) |
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_RL buoyKM1 (1-OLx:sNx+OLx,1-OLy:sNy+OLy) |
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_RL buoyK (1-OLx:sNx+OLx,1-OLy:sNy+OLy) |
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_RL rhotmp (1-OLx:sNx+OLx,1-OLy:sNy+OLy) |
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_RL etaSurfX(1-OLx:sNx+OLx,1-OLy:sNy+OLy) |
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_RL etaSurfY(1-OLx:sNx+OLx,1-OLy:sNy+OLy) |
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_RL K13 (1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr) |
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_RL K23 (1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr) |
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_RL K33 (1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr) |
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_RL KapGM (1-OLx:sNx+OLx,1-OLy:sNy+OLy) |
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_RL KappaRT (1-Olx:sNx+Olx,1-Oly:sNy+Oly,Nr) |
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_RL KappaRS (1-Olx:sNx+Olx,1-Oly:sNy+Oly,Nr) |
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|
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INTEGER iMin, iMax |
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INTEGER jMin, jMax |
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INTEGER bi, bj |
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INTEGER i, j |
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INTEGER k, kM1, kUp, kDown |
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LOGICAL BOTTOM_LAYER |
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|
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C--- The algorithm... |
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C |
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C "Correction Step" |
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C ================= |
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C Here we update the horizontal velocities with the surface |
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C pressure such that the resulting flow is either consistent |
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C with the free-surface evolution or the rigid-lid: |
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C U[n] = U* + dt x d/dx P |
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C V[n] = V* + dt x d/dy P |
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C |
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C "Calculation of Gs" |
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C =================== |
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C This is where all the accelerations and tendencies (ie. |
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C phiHydysics, parameterizations etc...) are calculated |
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C rVel = sum_r ( div. u[n] ) |
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C rho = rho ( theta[n], salt[n] ) |
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C b = b(rho, theta) |
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C K31 = K31 ( rho ) |
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C Gu[n] = Gu( u[n], v[n], rVel, b, ... ) |
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C Gv[n] = Gv( u[n], v[n], rVel, b, ... ) |
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C Gt[n] = Gt( theta[n], u[n], v[n], rVel, K31, ... ) |
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C Gs[n] = Gs( salt[n], u[n], v[n], rVel, K31, ... ) |
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C |
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C "Time-stepping" or "Prediction" |
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C ================================ |
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C The models variables are stepped forward with the appropriate |
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C time-stepping scheme (currently we use Adams-Bashforth II) |
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C - For momentum, the result is always *only* a "prediction" |
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C in that the flow may be divergent and will be "corrected" |
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C later with a surface pressure gradient. |
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C - Normally for tracers the result is the new field at time |
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C level [n+1} *BUT* in the case of implicit diffusion the result |
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C is also *only* a prediction. |
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C - We denote "predictors" with an asterisk (*). |
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C U* = U[n] + dt x ( 3/2 Gu[n] - 1/2 Gu[n-1] ) |
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C V* = V[n] + dt x ( 3/2 Gv[n] - 1/2 Gv[n-1] ) |
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C theta[n+1] = theta[n] + dt x ( 3/2 Gt[n] - 1/2 atG[n-1] ) |
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C salt[n+1] = salt[n] + dt x ( 3/2 Gt[n] - 1/2 atG[n-1] ) |
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C With implicit diffusion: |
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C theta* = theta[n] + dt x ( 3/2 Gt[n] - 1/2 atG[n-1] ) |
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C salt* = salt[n] + dt x ( 3/2 Gt[n] - 1/2 atG[n-1] ) |
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C (1 + dt * K * d_zz) theta[n] = theta* |
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C (1 + dt * K * d_zz) salt[n] = salt* |
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C--- |
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|
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C-- Set up work arrays with valid (i.e. not NaN) values |
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C These inital values do not alter the numerical results. They |
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C just ensure that all memory references are to valid floating |
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C point numbers. This prevents spurious hardware signals due to |
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C uninitialised but inert locations. |
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DO j=1-OLy,sNy+OLy |
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DO i=1-OLx,sNx+OLx |
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xA(i,j) = 0. _d 0 |
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yA(i,j) = 0. _d 0 |
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uTrans(i,j) = 0. _d 0 |
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vTrans(i,j) = 0. _d 0 |
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aTerm(i,j) = 0. _d 0 |
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xTerm(i,j) = 0. _d 0 |
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cTerm(i,j) = 0. _d 0 |
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mTerm(i,j) = 0. _d 0 |
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pTerm(i,j) = 0. _d 0 |
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fZon(i,j) = 0. _d 0 |
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fMer(i,j) = 0. _d 0 |
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DO K=1,Nr |
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phiHyd (i,j,k) = 0. _d 0 |
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K13(i,j,k) = 0. _d 0 |
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K23(i,j,k) = 0. _d 0 |
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K33(i,j,k) = 0. _d 0 |
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KappaRT(i,j,k) = 0. _d 0 |
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KappaRS(i,j,k) = 0. _d 0 |
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ENDDO |
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rhoKM1 (i,j) = 0. _d 0 |
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rhok (i,j) = 0. _d 0 |
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rhoKP1 (i,j) = 0. _d 0 |
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rhoTMP (i,j) = 0. _d 0 |
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buoyKM1(i,j) = 0. _d 0 |
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buoyK (i,j) = 0. _d 0 |
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maskC (i,j) = 0. _d 0 |
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ENDDO |
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ENDDO |
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|
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|
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DO bj=myByLo(myThid),myByHi(myThid) |
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DO bi=myBxLo(myThid),myBxHi(myThid) |
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|
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C-- Set up work arrays that need valid initial values |
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DO j=1-OLy,sNy+OLy |
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DO i=1-OLx,sNx+OLx |
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rTrans(i,j) = 0. _d 0 |
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rVel (i,j,1) = 0. _d 0 |
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rVel (i,j,2) = 0. _d 0 |
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fVerT (i,j,1) = 0. _d 0 |
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fVerT (i,j,2) = 0. _d 0 |
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fVerS (i,j,1) = 0. _d 0 |
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fVerS (i,j,2) = 0. _d 0 |
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fVerU (i,j,1) = 0. _d 0 |
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fVerU (i,j,2) = 0. _d 0 |
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fVerV (i,j,1) = 0. _d 0 |
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fVerV (i,j,2) = 0. _d 0 |
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phiHyd(i,j,1) = 0. _d 0 |
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K13 (i,j,1) = 0. _d 0 |
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K23 (i,j,1) = 0. _d 0 |
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K33 (i,j,1) = 0. _d 0 |
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KapGM (i,j) = GMkbackground |
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ENDDO |
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ENDDO |
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|
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iMin = 1-OLx+1 |
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iMax = sNx+OLx |
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jMin = 1-OLy+1 |
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jMax = sNy+OLy |
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|
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|
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K = 1 |
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BOTTOM_LAYER = K .EQ. Nr |
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|
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#ifdef DO_PIPELINED_CORRECTION_STEP |
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C-- Calculate gradient of surface pressure |
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CALL CALC_GRAD_ETA_SURF( |
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I bi,bj,iMin,iMax,jMin,jMax, |
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O etaSurfX,etaSurfY, |
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I myThid) |
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C-- Update fields in top level according to tendency terms |
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CALL CORRECTION_STEP( |
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I bi,bj,iMin,iMax,jMin,jMax,K, |
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I etaSurfX,etaSurfY,myTime,myThid) |
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IF (openBoundaries) CALL APPLY_OBCS1( bi, bj, K, myThid ) |
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IF ( .NOT. BOTTOM_LAYER ) THEN |
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C-- Update fields in layer below according to tendency terms |
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CALL CORRECTION_STEP( |
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I bi,bj,iMin,iMax,jMin,jMax,K+1, |
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I etaSurfX,etaSurfY,myTime,myThid) |
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IF (openBoundaries) CALL APPLY_OBCS1( bi, bj, K+1, myThid ) |
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ENDIF |
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#endif |
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C-- Density of 1st level (below W(1)) reference to level 1 |
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#ifdef INCLUDE_FIND_RHO_CALL |
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CALL FIND_RHO( |
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I bi, bj, iMin, iMax, jMin, jMax, K, K, eosType, |
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O rhoKm1, |
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I myThid ) |
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#endif |
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|
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IF ( .NOT. BOTTOM_LAYER ) THEN |
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C-- Check static stability with layer below |
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C-- and mix as needed. |
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#ifdef INCLUDE_FIND_RHO_CALL |
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CALL FIND_RHO( |
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I bi, bj, iMin, iMax, jMin, jMax, K+1, K, eosType, |
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O rhoKp1, |
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I myThid ) |
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#endif |
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#ifdef INCLUDE_CONVECT_CALL |
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CALL CONVECT( |
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I bi,bj,iMin,iMax,jMin,jMax,K+1,rhoKm1,rhoKp1, |
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I myTime,myIter,myThid) |
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#endif |
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C-- Recompute density after mixing |
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#ifdef INCLUDE_FIND_RHO_CALL |
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CALL FIND_RHO( |
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I bi, bj, iMin, iMax, jMin, jMax, K, K, eosType, |
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O rhoKm1, |
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I myThid ) |
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#endif |
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ENDIF |
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C-- Calculate buoyancy |
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CALL CALC_BUOYANCY( |
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I bi,bj,iMin,iMax,jMin,jMax,K,rhoKm1, |
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O buoyKm1, |
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I myThid ) |
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C-- Integrate hydrostatic balance for phiHyd with BC of |
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C-- phiHyd(z=0)=0 |
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CALL CALC_PHI_HYD( |
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I bi,bj,iMin,iMax,jMin,jMax,K,buoyKm1,buoyKm1, |
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U phiHyd, |
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I myThid ) |
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|
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DO K=2,Nr |
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BOTTOM_LAYER = K .EQ. Nr |
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#ifdef DO_PIPELINED_CORRECTION_STEP |
308 |
IF ( .NOT. BOTTOM_LAYER ) THEN |
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C-- Update fields in layer below according to tendency terms |
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CALL CORRECTION_STEP( |
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I bi,bj,iMin,iMax,jMin,jMax,K+1, |
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I etaSurfX,etaSurfY,myTime,myThid) |
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IF (openBoundaries) CALL APPLY_OBCS1( bi, bj, K+1, myThid ) |
314 |
ENDIF |
315 |
#endif |
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C-- Density of K level (below W(K)) reference to K level |
317 |
#ifdef INCLUDE_FIND_RHO_CALL |
318 |
CALL FIND_RHO( |
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I bi, bj, iMin, iMax, jMin, jMax, K, K, eosType, |
320 |
O rhoK, |
321 |
I myThid ) |
322 |
#endif |
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IF ( .NOT. BOTTOM_LAYER ) THEN |
324 |
C-- Check static stability with layer below and mix as needed. |
325 |
C-- Density of K+1 level (below W(K+1)) reference to K level. |
326 |
#ifdef INCLUDE_FIND_RHO_CALL |
327 |
CALL FIND_RHO( |
328 |
I bi, bj, iMin, iMax, jMin, jMax, K+1, K, eosType, |
329 |
O rhoKp1, |
330 |
I myThid ) |
331 |
#endif |
332 |
#ifdef INCLUDE_CONVECT_CALL |
333 |
CALL CONVECT( |
334 |
I bi,bj,iMin,iMax,jMin,jMax,K+1,rhoK,rhoKp1, |
335 |
I myTime,myIter,myThid) |
336 |
#endif |
337 |
C-- Recompute density after mixing |
338 |
#ifdef INCLUDE_FIND_RHO_CALL |
339 |
CALL FIND_RHO( |
340 |
I bi, bj, iMin, iMax, jMin, jMax, K, K, eosType, |
341 |
O rhoK, |
342 |
I myThid ) |
343 |
#endif |
344 |
ENDIF |
345 |
C-- Calculate buoyancy |
346 |
CALL CALC_BUOYANCY( |
347 |
I bi,bj,iMin,iMax,jMin,jMax,K,rhoK, |
348 |
O buoyK, |
349 |
I myThid ) |
350 |
C-- Integrate hydrostatic balance for phiHyd with BC of |
351 |
C-- phiHyd(z=0)=0 |
352 |
CALL CALC_PHI_HYD( |
353 |
I bi,bj,iMin,iMax,jMin,jMax,K,buoyKm1,buoyK, |
354 |
U phiHyd, |
355 |
I myThid ) |
356 |
C-- Calculate iso-neutral slopes for the GM/Redi parameterisation |
357 |
#ifdef INCLUDE_FIND_RHO_CALL |
358 |
CALL FIND_RHO( |
359 |
I bi, bj, iMin, iMax, jMin, jMax, K-1, K, eosType, |
360 |
O rhoTmp, |
361 |
I myThid ) |
362 |
#endif |
363 |
#ifdef INCLUDE_CALC_ISOSLOPES_CALL |
364 |
CALL CALC_ISOSLOPES( |
365 |
I bi, bj, iMin, iMax, jMin, jMax, K, |
366 |
I rhoKm1, rhoK, rhotmp, |
367 |
O K13, K23, K33, KapGM, |
368 |
I myThid ) |
369 |
#endif |
370 |
DO J=jMin,jMax |
371 |
DO I=iMin,iMax |
372 |
#ifdef INCLUDE_FIND_RHO_CALL |
373 |
rhoKm1 (I,J) = rhoK(I,J) |
374 |
#endif |
375 |
buoyKm1(I,J) = buoyK(I,J) |
376 |
ENDDO |
377 |
ENDDO |
378 |
ENDDO ! K |
379 |
|
380 |
DO K = Nr, 1, -1 |
381 |
|
382 |
kM1 =max(1,k-1) ! Points to level above k (=k-1) |
383 |
kUp =1+MOD(k+1,2) ! Cycles through 1,2 to point to layer above |
384 |
kDown=1+MOD(k,2) ! Cycles through 2,1 to point to current layer |
385 |
iMin = 1-OLx+2 |
386 |
iMax = sNx+OLx-1 |
387 |
jMin = 1-OLy+2 |
388 |
jMax = sNy+OLy-1 |
389 |
|
390 |
C-- Get temporary terms used by tendency routines |
391 |
CALL CALC_COMMON_FACTORS ( |
392 |
I bi,bj,iMin,iMax,jMin,jMax,k,kM1,kUp,kDown, |
393 |
O xA,yA,uTrans,vTrans,rTrans,rVel,maskC,maskUp, |
394 |
I myThid) |
395 |
#ifdef INCLUDE_CALC_DIFFUSIVITY_CALL |
396 |
C-- Calculate the total vertical diffusivity |
397 |
CALL CALC_DIFFUSIVITY( |
398 |
I bi,bj,iMin,iMax,jMin,jMax,K, |
399 |
I maskC,maskUp,KapGM,K33, |
400 |
O KappaRT,KappaRS, |
401 |
I myThid) |
402 |
#endif |
403 |
C-- Calculate accelerations in the momentum equations |
404 |
IF ( momStepping ) THEN |
405 |
CALL CALC_MOM_RHS( |
406 |
I bi,bj,iMin,iMax,jMin,jMax,k,kM1,kUp,kDown, |
407 |
I xA,yA,uTrans,vTrans,rTrans,rVel,maskC, |
408 |
I phiHyd, |
409 |
U aTerm,xTerm,cTerm,mTerm,pTerm, |
410 |
U fZon, fMer, fVerU, fVerV, |
411 |
I myTime, myThid) |
412 |
ENDIF |
413 |
C-- Calculate active tracer tendencies |
414 |
IF ( tempStepping ) THEN |
415 |
CALL CALC_GT( |
416 |
I bi,bj,iMin,iMax,jMin,jMax, k,kM1,kUp,kDown, |
417 |
I xA,yA,uTrans,vTrans,rTrans,maskUp,maskC, |
418 |
I K13,K23,KappaRT,KapGM, |
419 |
U aTerm,xTerm,fZon,fMer,fVerT, |
420 |
I myTime, myThid) |
421 |
ENDIF |
422 |
IF ( saltStepping ) THEN |
423 |
CALL CALC_GS( |
424 |
I bi,bj,iMin,iMax,jMin,jMax, k,kM1,kUp,kDown, |
425 |
I xA,yA,uTrans,vTrans,rTrans,maskUp,maskC, |
426 |
I K13,K23,KappaRS,KapGM, |
427 |
U aTerm,xTerm,fZon,fMer,fVerS, |
428 |
I myTime, myThid) |
429 |
ENDIF |
430 |
C-- Prediction step (step forward all model variables) |
431 |
CALL TIMESTEP( |
432 |
I bi,bj,iMin,iMax,jMin,jMax,K, |
433 |
I myThid) |
434 |
IF (openBoundaries) CALL APPLY_OBCS2( bi, bj, K, myThid ) |
435 |
C-- Diagnose barotropic divergence of predicted fields |
436 |
CALL CALC_DIV_GHAT( |
437 |
I bi,bj,iMin,iMax,jMin,jMax,K, |
438 |
I xA,yA, |
439 |
I myThid) |
440 |
|
441 |
C-- Cumulative diagnostic calculations (ie. time-averaging) |
442 |
#ifdef INCLUDE_DIAGNOSTICS_INTERFACE_CODE |
443 |
IF (taveFreq.GT.0.) THEN |
444 |
CALL DO_TIME_AVERAGES( |
445 |
I myTime, myIter, bi, bj, K, kUp, kDown, |
446 |
I K13, K23, rVel, KapGM, |
447 |
I myThid ) |
448 |
ENDIF |
449 |
#endif |
450 |
|
451 |
ENDDO ! K |
452 |
|
453 |
C-- Implicit diffusion |
454 |
IF (implicitDiffusion) THEN |
455 |
CALL IMPLDIFF( bi, bj, iMin, iMax, jMin, jMax, |
456 |
I KappaRT,KappaRS, |
457 |
I myThid ) |
458 |
ENDIF |
459 |
|
460 |
ENDDO |
461 |
ENDDO |
462 |
|
463 |
C write(0,*) 'dynamics: pS ',minval(cg2d_x(1:sNx,1:sNy,:,:)), |
464 |
C & maxval(cg2d_x(1:sNx,1:sNy,:,:)) |
465 |
C write(0,*) 'dynamics: U ',minval(uVel(1:sNx,1:sNy,1,:,:),mask=uVel(1:sNx,1:sNy,1,:,:).NE.0.), |
466 |
C & maxval(uVel(1:sNx,1:sNy,1,:,:),mask=uVel(1:sNx,1:sNy,1,:,:).NE.0.) |
467 |
C write(0,*) 'dynamics: V ',minval(vVel(1:sNx,1:sNy,1,:,:),mask=vVel(1:sNx,1:sNy,1,:,:).NE.0.), |
468 |
C & maxval(vVel(1:sNx,1:sNy,1,:,:),mask=vVel(1:sNx,1:sNy,1,:,:).NE.0.) |
469 |
C write(0,*) 'dynamics: rVel(1) ', |
470 |
C & minval(rVel(1:sNx,1:sNy,1),mask=rVel(1:sNx,1:sNy,1).NE.0.), |
471 |
C & maxval(rVel(1:sNx,1:sNy,1),mask=rVel(1:sNx,1:sNy,1).NE.0.) |
472 |
C write(0,*) 'dynamics: rVel(2) ', |
473 |
C & minval(rVel(1:sNx,1:sNy,2),mask=rVel(1:sNx,1:sNy,2).NE.0.), |
474 |
C & maxval(rVel(1:sNx,1:sNy,2),mask=rVel(1:sNx,1:sNy,2).NE.0.) |
475 |
cblk write(0,*) 'dynamics: K13',minval(K13(1:sNx,1:sNy,:)), |
476 |
cblk & maxval(K13(1:sNx,1:sNy,:)) |
477 |
cblk write(0,*) 'dynamics: K23',minval(K23(1:sNx,1:sNy,:)), |
478 |
cblk & maxval(K23(1:sNx,1:sNy,:)) |
479 |
cblk write(0,*) 'dynamics: K33',minval(K33(1:sNx,1:sNy,:)), |
480 |
cblk & maxval(K33(1:sNx,1:sNy,:)) |
481 |
C write(0,*) 'dynamics: gT ',minval(gT(1:sNx,1:sNy,:,:,:)), |
482 |
C & maxval(gT(1:sNx,1:sNy,:,:,:)) |
483 |
C write(0,*) 'dynamics: T ',minval(Theta(1:sNx,1:sNy,:,:,:)), |
484 |
C & maxval(Theta(1:sNx,1:sNy,:,:,:)) |
485 |
C write(0,*) 'dynamics: gS ',minval(gS(1:sNx,1:sNy,:,:,:)), |
486 |
C & maxval(gS(1:sNx,1:sNy,:,:,:)) |
487 |
C write(0,*) 'dynamics: S ',minval(salt(1:sNx,1:sNy,:,:,:)), |
488 |
C & maxval(salt(1:sNx,1:sNy,:,:,:)) |
489 |
C write(0,*) 'dynamics: phiHyd ',minval(phiHyd/(Gravity*Rhonil),mask=phiHyd.NE.0.), |
490 |
C & maxval(phiHyd/(Gravity*Rhonil)) |
491 |
C CALL PLOT_FIELD_XYZRL( gU, ' GU exiting dyanmics ' , |
492 |
C &Nr, 1, myThid ) |
493 |
C CALL PLOT_FIELD_XYZRL( gV, ' GV exiting dyanmics ' , |
494 |
C &Nr, 1, myThid ) |
495 |
C CALL PLOT_FIELD_XYZRL( gS, ' GS exiting dyanmics ' , |
496 |
C &Nr, 1, myThid ) |
497 |
C CALL PLOT_FIELD_XYZRL( gT, ' GT exiting dyanmics ' , |
498 |
C &Nr, 1, myThid ) |
499 |
C CALL PLOT_FIELD_XYZRL( phiHyd, ' phiHyd exiting dyanmics ' , |
500 |
C &Nr, 1, myThid ) |
501 |
|
502 |
|
503 |
RETURN |
504 |
END |