(PID.TID 0000.0001) (PID.TID 0000.0001) // ====================================================== (PID.TID 0000.0001) // MITgcm UV (PID.TID 0000.0001) // ========= (PID.TID 0000.0001) // ====================================================== (PID.TID 0000.0001) // execution environment starting up... (PID.TID 0000.0001) (PID.TID 0000.0001) // MITgcmUV version: checkpoint65q (PID.TID 0000.0001) // Build user: jamrda26 (PID.TID 0000.0001) // Build host: bslscihub-ws2 (PID.TID 0000.0001) // Build date: Fri Jan 8 14:27:16 GMT 2016 (PID.TID 0000.0001) (PID.TID 0000.0001) // ======================================================= (PID.TID 0000.0001) // Execution Environment parameter file "eedata" (PID.TID 0000.0001) // ======================================================= (PID.TID 0000.0001) ># Example "eedata" file (PID.TID 0000.0001) ># Lines beginning "#" are comments (PID.TID 0000.0001) ># nTx - No. threads per process in X (PID.TID 0000.0001) ># nTy - No. threads per process in Y (PID.TID 0000.0001) > &EEPARMS (PID.TID 0000.0001) > & (PID.TID 0000.0001) ># Note: Some systems use & as the (PID.TID 0000.0001) ># namelist terminator. Other systems (PID.TID 0000.0001) ># use a / character (as shown here). (PID.TID 0000.0001) (PID.TID 0000.0001) // ======================================================= (PID.TID 0000.0001) // Computational Grid Specification ( see files "SIZE.h" ) (PID.TID 0000.0001) // ( and "eedata" ) (PID.TID 0000.0001) // ======================================================= (PID.TID 0000.0001) nPx = 1 ; /* No. processes in X */ (PID.TID 0000.0001) nPy = 1 ; /* No. processes in Y */ (PID.TID 0000.0001) nSx = 1 ; /* No. tiles in X per process */ (PID.TID 0000.0001) nSy = 1 ; /* No. tiles in Y per process */ (PID.TID 0000.0001) sNx = 1 ; /* Tile size in X */ (PID.TID 0000.0001) sNy = 200 ; /* Tile size in Y */ (PID.TID 0000.0001) OLx = 3 ; /* Tile overlap distance in X */ (PID.TID 0000.0001) OLy = 3 ; /* Tile overlap distance in Y */ (PID.TID 0000.0001) nTx = 1 ; /* No. threads in X per process */ (PID.TID 0000.0001) nTy = 1 ; /* No. threads in Y per process */ (PID.TID 0000.0001) Nr = 100 ; /* No. levels in the vertical */ (PID.TID 0000.0001) Nx = 1 ; /* Total domain size in X ( = nPx*nSx*sNx ) */ (PID.TID 0000.0001) Ny = 200 ; /* Total domain size in Y ( = nPy*nSy*sNy ) */ (PID.TID 0000.0001) nTiles = 1 ; /* Total no. tiles per process ( = nSx*nSy ) */ (PID.TID 0000.0001) nProcs = 1 ; /* Total no. processes ( = nPx*nPy ) */ (PID.TID 0000.0001) nThreads = 1 ; /* Total no. threads per process ( = nTx*nTy ) */ (PID.TID 0000.0001) usingMPI = T ; /* Flag used to control whether MPI is in use */ (PID.TID 0000.0001) /* note: To execute a program with MPI calls */ (PID.TID 0000.0001) /* it must be launched appropriately e.g */ (PID.TID 0000.0001) /* "mpirun -np 64 ......" */ (PID.TID 0000.0001) useCoupler= F ;/* Flag used to control communications with */ (PID.TID 0000.0001) /* other model components, through a coupler */ (PID.TID 0000.0001) debugMode = F ; /* print debug msg. (sequence of S/R calls) */ (PID.TID 0000.0001) printMapIncludesZeros= F ; /* print zeros in Std.Output maps */ (PID.TID 0000.0001) maxLengthPrt1D= 65 /* maxLength of 1D array printed to StdOut */ (PID.TID 0000.0001) (PID.TID 0000.0001) ======= Starting MPI parallel Run ========= (PID.TID 0000.0001) My Processor Name (len: 7 ) = node014 (PID.TID 0000.0001) Located at ( 0, 0) on processor grid (0: 0,0: 0) (PID.TID 0000.0001) Origin at ( 1, 1) on global grid (1: 1,1: 200) (PID.TID 0000.0001) North neighbor = processor 0000 (PID.TID 0000.0001) South neighbor = processor 0000 (PID.TID 0000.0001) East neighbor = processor 0000 (PID.TID 0000.0001) West neighbor = processor 0000 (PID.TID 0000.0001) // ====================================================== (PID.TID 0000.0001) // Mapping of tiles to threads (PID.TID 0000.0001) // ====================================================== (PID.TID 0000.0001) // -o- Thread 1, tiles ( 1: 1, 1: 1) (PID.TID 0000.0001) (PID.TID 0000.0001) // ====================================================== (PID.TID 0000.0001) // Tile <-> Tile connectvity table (PID.TID 0000.0001) // ====================================================== (PID.TID 0000.0001) // Tile number: 000001 (process no. = 000000) (PID.TID 0000.0001) // WEST: Tile = 000001, Process = 000000, Comm = put (PID.TID 0000.0001) // bi = 000001, bj = 000001 (PID.TID 0000.0001) // EAST: Tile = 000001, Process = 000000, Comm = put (PID.TID 0000.0001) // bi = 000001, bj = 000001 (PID.TID 0000.0001) // SOUTH: Tile = 000001, Process = 000000, Comm = put (PID.TID 0000.0001) // bi = 000001, bj = 000001 (PID.TID 0000.0001) // NORTH: Tile = 000001, Process = 000000, Comm = put (PID.TID 0000.0001) // bi = 000001, bj = 000001 (PID.TID 0000.0001) (PID.TID 0000.0001) INI_PARMS: opening model parameter file "data" (PID.TID 0000.0001) OPEN_COPY_DATA_FILE: opening file data (PID.TID 0000.0001) // ======================================================= (PID.TID 0000.0001) // Parameter file "data" (PID.TID 0000.0001) // ======================================================= (PID.TID 0000.0001) >#:::==================== (PID.TID 0000.0001) ># | Model parameters | (PID.TID 0000.0001) ># ==================== (PID.TID 0000.0001) ># (PID.TID 0000.0001) ># Continuous equation parameters (PID.TID 0000.0001) > &PARM01 (PID.TID 0000.0001) ># momstepping=.FALSE., (PID.TID 0000.0001) ># tempstepping=.FALSE., (PID.TID 0000.0001) ># saltstepping=.FALSE., (PID.TID 0000.0001) > Tref = 50*-1.9, (PID.TID 0000.0001) > Sref = 50*34.4, (PID.TID 0000.0001) > viscAr=1.E-3, (PID.TID 0000.0001) >#viscAh=600.0, (PID.TID 0000.0001) > viscAhGrid=0.2, (PID.TID 0000.0001) > viscA4Grid=0.02, (PID.TID 0000.0001) > no_slip_sides=.FALSE., (PID.TID 0000.0001) > no_slip_bottom=.FALSE., (PID.TID 0000.0001) > diffKhT= 100.0, (PID.TID 0000.0001) >#diffKhT= 600.0, (PID.TID 0000.0001) > diffKrT=5.E-5, (PID.TID 0000.0001) > diffKhS= 100.0, (PID.TID 0000.0001) >#diffKhS= 600.0, (PID.TID 0000.0001) > diffKrS=5.E-5, (PID.TID 0000.0001) > bottomDragQuadratic=2.5E-3, (PID.TID 0000.0001) > staggerTimestep = .true., (PID.TID 0000.0001) > tempAdvScheme=30, (PID.TID 0000.0001) > saltAdvScheme=30, (PID.TID 0000.0001) > vectorInvariantMomentum = .true., (PID.TID 0000.0001) >### momImplVertAdv=.true., (PID.TID 0000.0001) > tempImplVertAdv=.true., (PID.TID 0000.0001) > saltImplVertAdv=.true., (PID.TID 0000.0001) > eosType='JMD95Z', (PID.TID 0000.0001) >#tAlpha = 2.E-4, (PID.TID 0000.0001) >#sBeta = 7.4E-4, (PID.TID 0000.0001) > HeatCapacity_cp = 3974.0, (PID.TID 0000.0001) > rhoConst=1000., (PID.TID 0000.0001) > rhoNil=1000., (PID.TID 0000.0001) > gravity=9.81, (PID.TID 0000.0001) > gBaro=9.81, (PID.TID 0000.0001) > implicitDiffusion = .true., (PID.TID 0000.0001) > implicitViscosity = .true., (PID.TID 0000.0001) > rigidLid=.FALSE., (PID.TID 0000.0001) > implicitFreeSurface=.TRUE., (PID.TID 0000.0001) > useRealFreshWaterFlux = .true., (PID.TID 0000.0001) > exactConserv=.TRUE., (PID.TID 0000.0001) ># start nlfs with rstar (PID.TID 0000.0001) >#select_rStar=2, (PID.TID 0000.0001) >nonlinFreeSurf=4, (PID.TID 0000.0001) >hFacInf=0.2, (PID.TID 0000.0001) >hFacSup=2.0, (PID.TID 0000.0001) ># end nlfs with rstar (PID.TID 0000.0001) > hFacMin=0.2, (PID.TID 0000.0001) >#integr_GeoPot = 1, (PID.TID 0000.0001) >#ivdc_kappa = 0.005., (PID.TID 0000.0001) >#implicitDiffusion=.true., (PID.TID 0000.0001) >#implicitViscosity=.true., (PID.TID 0000.0001) >#useCDscheme=.true., (PID.TID 0000.0001) >#nonHydrostatic=.true., (PID.TID 0000.0001) >#allowFreezing = .true., (PID.TID 0000.0001) > readBinaryPrec=64, (PID.TID 0000.0001) >#writeBinaryPrec=64, (PID.TID 0000.0001) > debuglevel = 1, (PID.TID 0000.0001) > selectCoriMap = 0, (PID.TID 0000.0001) > f0 = 0.0, (PID.TID 0000.0001) ># useSingleCpuIO=.TRUE., (PID.TID 0000.0001) > globalFiles=.TRUE., (PID.TID 0000.0001) > & (PID.TID 0000.0001) > (PID.TID 0000.0001) ># Elliptic solver parameters (PID.TID 0000.0001) > &PARM02 (PID.TID 0000.0001) > cg2dMaxIters=300, (PID.TID 0000.0001) > cg2dTargetResidual=1.E-11, (PID.TID 0000.0001) >#cg3dMaxIters=40, (PID.TID 0000.0001) >#cg3dTargetResidual=1.E-13, (PID.TID 0000.0001) > & (PID.TID 0000.0001) > (PID.TID 0000.0001) >#Time stepping parameters (PID.TID 0000.0001) > &PARM03 (PID.TID 0000.0001) >#niter0=0, (PID.TID 0000.0001) > nTimeSteps=10., (PID.TID 0000.0001) ># nTimeSteps=1, (PID.TID 0000.0001) > startTime=2592000., (PID.TID 0000.0001) ># startTime = 0., (PID.TID 0000.0001) >#startTime=62208000., (PID.TID 0000.0001) >#startTime=15552000., (PID.TID 0000.0001) >#endTime=2593000., (PID.TID 0000.0001) >deltaT=600.0, (PID.TID 0000.0001) >### deltaT=1200.0, (PID.TID 0000.0001) > forcing_In_AB = .false., (PID.TID 0000.0001) >#rCD = 0.9896, (PID.TID 0000.0001) > abEps=0.1, (PID.TID 0000.0001) > cAdjFreq = -1., (PID.TID 0000.0001) > pChkptFreq=2592000.0, (PID.TID 0000.0001) > chkptFreq=2592000.0, (PID.TID 0000.0001) ># pChkptFreq=600.0, (PID.TID 0000.0001) ># chkptFreq=600.0, (PID.TID 0000.0001) > monitorFreq=2592000., (PID.TID 0000.0001) > dumpFreq=2592000, (PID.TID 0000.0001) > & (PID.TID 0000.0001) > (PID.TID 0000.0001) ># Gridding parameters (PID.TID 0000.0001) > &PARM04 (PID.TID 0000.0001) > usingCartesianGrid=.FALSE., (PID.TID 0000.0001) > usingSphericalPolarGrid=.TRUE., (PID.TID 0000.0001) >#delR = 10., 10., 10., 10., 10., 10., 10., 10.01, 10.03, 10.11, (PID.TID 0000.0001) >#10.32, 10.8, 11.76, 13.42, 16.04, 19.82, 24.85, 31.1, 38.42, 46.5, (PID.TID 0000.0001) >#55., 63.5, 71.58, 78.9, 85.15, 90.18, 93.96, 96.58, 98.25, 99.25, (PID.TID 0000.0001) >#100.01, 101.33, 104.56, 111.33, 122.83, 139.09, 158.94, 180.83, 203.55, 226.5, (PID.TID 0000.0001) >#249.5, 272.5, 295.5, 318.5, 341.5, 364.5, 387.5, 410.5, 433.5, 456.5, (PID.TID 0000.0001) > delR=100*10., (PID.TID 0000.0001) > delX=1*.125, (PID.TID 0000.0001) > delY=200*.0078125 (PID.TID 0000.0001) ># delYFile='dlat.bin', (PID.TID 0000.0001) ># delY=30*10e3, (PID.TID 0000.0001) > xgOrigin = -105.5, (PID.TID 0000.0001) > ygOrigin = -75.4457, (PID.TID 0000.0001) > & (PID.TID 0000.0001) > (PID.TID 0000.0001) ># Input datasets (PID.TID 0000.0001) > &PARM05 (PID.TID 0000.0001) > bathyFile='bathymetry.pig.bin', (PID.TID 0000.0001) > hydrogThetaFile='theta.init', (PID.TID 0000.0001) > hydrogSaltFile='salt.init', (PID.TID 0000.0001) > pSurfInitFile='etainit.round.bin' (PID.TID 0000.0001) > (PID.TID 0000.0001) > & (PID.TID 0000.0001) (PID.TID 0000.0001) INI_PARMS ; starts to read PARM01 (PID.TID 0000.0001) INI_PARMS ; read PARM01 : OK (PID.TID 0000.0001) INI_PARMS ; starts to read PARM02 (PID.TID 0000.0001) INI_PARMS ; read PARM02 : OK (PID.TID 0000.0001) INI_PARMS ; starts to read PARM03 (PID.TID 0000.0001) INI_PARMS ; read PARM03 : OK (PID.TID 0000.0001) INI_PARMS ; starts to read PARM04 (PID.TID 0000.0001) INI_PARMS ; read PARM04 : OK (PID.TID 0000.0001) INI_PARMS ; starts to read PARM05 (PID.TID 0000.0001) INI_PARMS ; read PARM05 : OK (PID.TID 0000.0001) INI_PARMS: finished reading file "data" (PID.TID 0000.0001) PACKAGES_BOOT: opening data.pkg (PID.TID 0000.0001) OPEN_COPY_DATA_FILE: opening file data.pkg (PID.TID 0000.0001) // ======================================================= (PID.TID 0000.0001) // Parameter file "data.pkg" (PID.TID 0000.0001) // ======================================================= (PID.TID 0000.0001) ># Packages (PID.TID 0000.0001) > &PACKAGES (PID.TID 0000.0001) >#useKPP=.true., (PID.TID 0000.0001) > useOBCS=.true., (PID.TID 0000.0001) > useMNC=.FALSE., (PID.TID 0000.0001) > useShelfIce=.true., (PID.TID 0000.0001) ># useStreamIce=.true., (PID.TID 0000.0001) >#useSEAICE=.true., (PID.TID 0000.0001) > useDiagnostics = .true., (PID.TID 0000.0001) > & (PID.TID 0000.0001) (PID.TID 0000.0001) PACKAGES_BOOT: finished reading data.pkg (PID.TID 0000.0001) PACKAGES_BOOT: On/Off package Summary -------- pkgs with a standard "usePKG" On/Off switch in "data.pkg": -------- pkg/obcs compiled and used ( useOBCS = T ) pkg/shelfice compiled and used ( useShelfIce = T ) pkg/streamice compiled but not used ( useStreamIce = F ) pkg/diagnostics compiled and used ( useDiagnostics = T ) -------- pkgs without standard "usePKG" On/Off switch in "data.pkg": -------- pkg/generic_advdiff compiled and used ( useGAD = T ) pkg/mom_common compiled and used ( momStepping = T ) pkg/mom_vecinv compiled and used ( +vectorInvariantMomentum = T ) pkg/mom_fluxform compiled but not used ( & not vectorInvariantMom = F ) pkg/monitor compiled and used ( monitorFreq > 0. = T ) pkg/debug compiled but not used ( debugMode = F ) pkg/rw compiled and used pkg/mdsio compiled and used (PID.TID 0000.0001) PACKAGES_BOOT: End of package Summary (PID.TID 0000.0001) (PID.TID 0000.0001) OBCS_READPARMS: opening data.obcs (PID.TID 0000.0001) OPEN_COPY_DATA_FILE: opening file data.obcs (PID.TID 0000.0001) // ======================================================= (PID.TID 0000.0001) // Parameter file "data.obcs" (PID.TID 0000.0001) // ======================================================= (PID.TID 0000.0001) ># Open-boundaries (PID.TID 0000.0001) > &OBCS_PARM01 (PID.TID 0000.0001) > OB_Jnorth=1*200, (PID.TID 0000.0001) > useOBCSprescribe=.true., (PID.TID 0000.0001) > useOBCSsponge=.true., (PID.TID 0000.0001) ># OBWuFile='uvel.obw', (PID.TID 0000.0001) > OBNvFile='vvel.obw', (PID.TID 0000.0001) > OBNtFile='theta.obw', (PID.TID 0000.0001) > OBNsFile='salt.obw', (PID.TID 0000.0001) > useOrlanskiNorth=.FALSE., (PID.TID 0000.0001) > & (PID.TID 0000.0001) > (PID.TID 0000.0001) ># Orlanski parameters (PID.TID 0000.0001) > &OBCS_PARM02 (PID.TID 0000.0001) >#Cmax=0.45, (PID.TID 0000.0001) >#cVelTimeScale=1000., (PID.TID 0000.0001) > & (PID.TID 0000.0001) > (PID.TID 0000.0001) ># Sponge layer parameters (PID.TID 0000.0001) > &OBCS_PARM03 (PID.TID 0000.0001) > spongeThickness = 20, (PID.TID 0000.0001) > Vrelaxobcsbound = 864000, (PID.TID 0000.0001) > Urelaxobcsbound = 864000, (PID.TID 0000.0001) > & (PID.TID 0000.0001) (PID.TID 0000.0001) OBCS_READPARMS: finished reading data.obcs (PID.TID 0000.0001) OB_indexUnset = /* unset OB index value (i.e. no OB) */ (PID.TID 0000.0001) 0 (PID.TID 0000.0001) ; (PID.TID 0000.0001) Northern OB global indices : OB_Jnorth = (PID.TID 0000.0001) 200 /* I = 1 */ (PID.TID 0000.0001) Southern OB global indices : OB_Jsouth = (PID.TID 0000.0001) 0 /* I = 1 */ (PID.TID 0000.0001) Eastern OB global indices : OB_Ieast = (PID.TID 0000.0001) 200 @ 0 /* J = 1:200 */ (PID.TID 0000.0001) Western OB global indices : OB_Iwest = (PID.TID 0000.0001) 200 @ 0 /* J = 1:200 */ (PID.TID 0000.0001) (PID.TID 0000.0001) SHELFICE_READPARMS: opening data.shelfice (PID.TID 0000.0001) OPEN_COPY_DATA_FILE: opening file data.shelfice (PID.TID 0000.0001) // ======================================================= (PID.TID 0000.0001) // Parameter file "data.shelfice" (PID.TID 0000.0001) // ======================================================= (PID.TID 0000.0001) ># =================================== (PID.TID 0000.0001) ># | Parameters for SHELFICE package | (PID.TID 0000.0001) ># =================================== (PID.TID 0000.0001) > &SHELFICE_PARM01 (PID.TID 0000.0001) > SHELFICEwriteState = .true., (PID.TID 0000.0001) >#mult_shelfice=1., (PID.TID 0000.0001) >#useISOMIPTD = .true., (PID.TID 0000.0001) > SHELFICEconserve = .true., (PID.TID 0000.0001) > SHELFICEboundaryLayer = .true., (PID.TID 0000.0001) ># SHELFICEtopoFile='shelftopo.pig.bin', (PID.TID 0000.0001) > SHELFICEtopoFile='shelftopo.round.bin', (PID.TID 0000.0001) ># SHELFICEloadAnomalyFile = 'pload.pig.jmd95z', (PID.TID 0000.0001) ># SHELFICEMassDynTendFile = 'MDS.bin', (PID.TID 0000.0001) > SHELFICEGroundInitFile= 'shelficegroundinit.bin', (PID.TID 0000.0001) > SHELFICEGroundTopoFile= 'shelftopo.ground.bin', (PID.TID 0000.0001) > SHELFICErealFWflux =.true., (PID.TID 0000.0001) > SHELFICEmassFile = 'shelficemassinit.bin', (PID.TID 0000.0001) > SHELFICEuseGammaFrict = .true., (PID.TID 0000.0001) > SHELFICEDragQuadratic = 0.0015, (PID.TID 0000.0001) > shiCdrag = 0.0015 (PID.TID 0000.0001) > SHELFICEMassStepping = .true. (PID.TID 0000.0001) > SHELFICERemeshFrequency = 2593800.0, (PID.TID 0000.0001) > SHELFICESplitThreshold =2.5, (PID.TID 0000.0001) > SHELFICEMergeThreshold =-7.6, (PID.TID 0000.0001) > SHELFICEGroundC = 270000, (PID.TID 0000.0001) > SHELFICEGroundW = 1, (PID.TID 0000.0001) > & (PID.TID 0000.0001) (PID.TID 0000.0001) SHELFICE_READPARMS: finished reading data.shelfice (PID.TID 0000.0001) DIAGNOSTICS_READPARMS: opening data.diagnostics (PID.TID 0000.0001) OPEN_COPY_DATA_FILE: opening file data.diagnostics (PID.TID 0000.0001) // ======================================================= (PID.TID 0000.0001) // Parameter file "data.diagnostics" (PID.TID 0000.0001) // ======================================================= (PID.TID 0000.0001) ># Diagnostic Package Choices (PID.TID 0000.0001) >#----------------- (PID.TID 0000.0001) ># for each output-stream: (PID.TID 0000.0001) ># filename(n) : prefix of the output file name (only 8.c long) for outp.stream n (PID.TID 0000.0001) ># frequency(n):< 0 : write snap-shot output every |frequency| seconds (PID.TID 0000.0001) ># > 0 : write time-average output every frequency seconds (PID.TID 0000.0001) ># timePhase(n) : write at time = timePhase + multiple of |frequency| (PID.TID 0000.0001) ># averagingFreq(n) : frequency (in s) for periodic averaging interval (PID.TID 0000.0001) ># averagingPhase(n): phase (in s) for periodic averaging interval (PID.TID 0000.0001) ># repeatCycle(n) : number of averaging intervals in 1 cycle (PID.TID 0000.0001) ># levels(:,n) : list of levels to write to file (Notes: declared as REAL) (PID.TID 0000.0001) ># when this entry is missing, select all common levels of this list (PID.TID 0000.0001) ># fields(:,n) : list of diagnostics fields (8.c) (see "available_diagnostics.log" (PID.TID 0000.0001) ># file for the list of all available diag. in this particular config) (PID.TID 0000.0001) >#----------------- (PID.TID 0000.0001) > &DIAGNOSTICS_LIST (PID.TID 0000.0001) ># diag_mnc = .FALSE., (PID.TID 0000.0001) ># dumpAtLast = .TRUE., (PID.TID 0000.0001) > fields(1,1) = 'ETAN ','oceTAUX ','oceTAUY ', (PID.TID 0000.0001) > 'oceQnet ','oceFWflx','MXLDEPTH', (PID.TID 0000.0001) > 'SHIfwFlx','SHIhtFlx','SHIgammT','SHIgammS', (PID.TID 0000.0001) > 'SHI_mass','SHIuStar','SHI_Rshelfice' (PID.TID 0000.0001) ># 'SI_Uvel ','SI_Vvel ','SI_Thick','SI_hmask', (PID.TID 0000.0001) ># 'SHIuLocM','SHIvLocM','SHIwLocM','SHItLocM','SHIsLocM', (PID.TID 0000.0001) ># 'SHItLocB','SHIsLocB' (PID.TID 0000.0001) ># 'SHIForcT','SHIForcS', (PID.TID 0000.0001) ># 'surForcT','surForcS','TFLUX ','SFLUX ','oceFreez', (PID.TID 0000.0001) ># 'TRELAX ','SRELAX ', (PID.TID 0000.0001) ># 'GM_VisbK', (PID.TID 0000.0001) ># fields(1,1)='ETAN' (PID.TID 0000.0001) > filename(1) = 'surfDiag', (PID.TID 0000.0001) > frequency(1) = 600., (PID.TID 0000.0001) > fields(1,2) = 'UVEL ','VVEL ','WVEL ', (PID.TID 0000.0001) > 'THETA ','SALT ','RHOAnoma', 'CONVADJ' (PID.TID 0000.0001) > filename(2) = 'dynDiag', (PID.TID 0000.0001) > frequency(2) = 600., (PID.TID 0000.0001) ># fields(1,3) = 'SI_Uvel ','SI_Vvel ','SI_Thick','SI_hmask','SI_float' (PID.TID 0000.0001) ># filename(3) = 'streamice', (PID.TID 0000.0001) ># frequency(3) = 86400., (PID.TID 0000.0001) ># fields(1,3) = 'EXFpreci','EXFuwind','EXFvwind','EXFtaux ','EXFtauy ', (PID.TID 0000.0001) ># 'EXFlwdn ','EXFswdn ','EXFatemp','EXFaqh ','EXFpress', (PID.TID 0000.0001) ># 'GM_PsiX ','GM_PsiY ', (PID.TID 0000.0001) ># 'GM_Kwx ','GM_Kwy ','GM_Kwz ', (PID.TID 0000.0001) ># 'GM_Kux ','GM_Kvy ', (PID.TID 0000.0001) ># 'GM_Kuz ','GM_Kvz ', (PID.TID 0000.0001) >#- disable this output list by commenting out the file name (PID.TID 0000.0001) ># filename(3) = 'diagsEXF', (PID.TID 0000.0001) ># frequency(3) = 1., (PID.TID 0000.0001) ># fields(1,4) = 'ADVx_TH ','ADVy_TH ','ADVr_TH ', (PID.TID 0000.0001) ># 'DIFx_TH ','DIFy_TH ','DFrE_TH ', (PID.TID 0000.0001) ># 'DFrI_TH ', (PID.TID 0000.0001) ># 'ADVx_SLT', (PID.TID 0000.0001) ># filename(4) = 'flxDiag', (PID.TID 0000.0001) ># frequency(4) = 1296000., (PID.TID 0000.0001) > & (PID.TID 0000.0001) > (PID.TID 0000.0001) ># Parameter for Diagnostics of per level statistics: (PID.TID 0000.0001) >#----------------- (PID.TID 0000.0001) ># for each output-stream: (PID.TID 0000.0001) ># stat_fname(n) : prefix of the output file name (only 8.c long) for outp.stream n (PID.TID 0000.0001) ># stat_freq(n):< 0 : write snap-shot output every |stat_freq| seconds (PID.TID 0000.0001) ># > 0 : write time-average output every stat_freq seconds (PID.TID 0000.0001) ># stat_phase(n) : write at time = stat_phase + multiple of |stat_freq| (PID.TID 0000.0001) ># stat_region(:,n) : list of "regions" (default: 1 region only=global) (PID.TID 0000.0001) ># stat_fields(:,n) : list of diagnostics fields (8.c) (see "available_diagnostics.log" (PID.TID 0000.0001) ># file for the list of all available diag. in this particular config) (PID.TID 0000.0001) >#----------------- (PID.TID 0000.0001) > &DIAG_STATIS_PARMS (PID.TID 0000.0001) >#- regional mask: 3 lat. band: 1 : y <= -24 ; 2 : -24# diagSt_regMaskFile='regMask_lat24.bin', (PID.TID 0000.0001) ># nSetRegMskFile=1, (PID.TID 0000.0001) ># set_regMask(1)= 1, 1, 1, (PID.TID 0000.0001) ># val_regMask(1)= 1., 2., 3., (PID.TID 0000.0001) >#--- (PID.TID 0000.0001) >#stat_fields(1,1)= 'ETAN ','UVEL ','VVEL ','WVEL ', (PID.TID 0000.0001) ># 'THETA ','SALT ','SIarea ','SIheff ', (PID.TID 0000.0001) ># stat_fname(1)= 'dynStDiag', (PID.TID 0000.0001) ># stat_freq(1)= 864000., (PID.TID 0000.0001) > & (PID.TID 0000.0001) > (PID.TID 0000.0001) (PID.TID 0000.0001) S/R DIAGNOSTICS_READPARMS, read namelist "diagnostics_list": start (PID.TID 0000.0001) S/R DIAGNOSTICS_READPARMS, read namelist "diagnostics_list": OK (PID.TID 0000.0001) S/R DIAGNOSTICS_READPARMS, read namelist "DIAG_STATIS_PARMS": start (PID.TID 0000.0001) S/R DIAGNOSTICS_READPARMS, read namelist "DIAG_STATIS_PARMS": OK (PID.TID 0000.0001) DIAGNOSTICS_READPARMS: global parameter summary: (PID.TID 0000.0001) dumpAtLast = /* always write time-ave diags at the end */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) diag_mnc = /* write NetCDF output files */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) useMissingValue = /* put MissingValue where mask = 0 */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) diagCG_maxIters = /* max number of iters in diag_cg2d */ (PID.TID 0000.0001) 300 (PID.TID 0000.0001) ; (PID.TID 0000.0001) diagCG_resTarget = /* residual target for diag_cg2d */ (PID.TID 0000.0001) 9.999999999999999E-12 (PID.TID 0000.0001) ; (PID.TID 0000.0001) diagCG_pcOffDFac = /* preconditioner off-diagonal factor */ (PID.TID 0000.0001) 9.611687812379854E-01 (PID.TID 0000.0001) ; (PID.TID 0000.0001) ----------------------------------------------------- (PID.TID 0000.0001) DIAGNOSTICS_READPARMS: active diagnostics summary: (PID.TID 0000.0001) ----------------------------------------------------- (PID.TID 0000.0001) Creating Output Stream: surfDiag (PID.TID 0000.0001) Output Frequency: 600.000000 ; Phase: 0.000000 (PID.TID 0000.0001) Averaging Freq.: 600.000000 , Phase: 0.000000 , Cycle: 1 (PID.TID 0000.0001) missing value: -9.990000000000E+02 (PID.TID 0000.0001) Levels: will be set later (PID.TID 0000.0001) Fields: ETAN oceTAUX oceTAUY oceQnet oceFWflx MXLDEPTH SHIfwFlx SHIhtFlx SHIgammT SHIgammS (PID.TID 0000.0001) Fields: SHI_mass SHIuStar SHI_Rshe (PID.TID 0000.0001) Creating Output Stream: dynDiag (PID.TID 0000.0001) Output Frequency: 600.000000 ; Phase: 0.000000 (PID.TID 0000.0001) Averaging Freq.: 600.000000 , Phase: 0.000000 , Cycle: 1 (PID.TID 0000.0001) missing value: -9.990000000000E+02 (PID.TID 0000.0001) Levels: will be set later (PID.TID 0000.0001) Fields: UVEL VVEL WVEL THETA SALT RHOAnoma CONVADJ (PID.TID 0000.0001) ----------------------------------------------------- (PID.TID 0000.0001) DIAGNOSTICS_READPARMS: statistics diags. summary: (PID.TID 0000.0001) ----------------------------------------------------- (PID.TID 0000.0001) ----------------------------------------------------- (PID.TID 0000.0001) SET_PARMS: done (PID.TID 0000.0001) Enter INI_VERTICAL_GRID: setInterFDr= T ; setCenterDr= F (PID.TID 0000.0001) %MON XC_max = -1.0543750000000E+02 (PID.TID 0000.0001) %MON XC_min = -1.0543750000000E+02 (PID.TID 0000.0001) %MON XC_mean = -1.0543750000000E+02 (PID.TID 0000.0001) %MON XC_sd = 0.0000000000000E+00 (PID.TID 0000.0001) %MON XG_max = -1.0550000000000E+02 (PID.TID 0000.0001) %MON XG_min = -1.0550000000000E+02 (PID.TID 0000.0001) %MON XG_mean = -1.0550000000000E+02 (PID.TID 0000.0001) %MON XG_sd = 0.0000000000000E+00 (PID.TID 0000.0001) %MON DXC_max = 3.8568974527819E+03 (PID.TID 0000.0001) %MON DXC_min = 3.4932435587116E+03 (PID.TID 0000.0001) %MON DXC_mean = 3.6752948781653E+03 (PID.TID 0000.0001) %MON DXC_sd = 1.0550536922206E+02 (PID.TID 0000.0001) %MON DXF_max = 3.8568974527819E+03 (PID.TID 0000.0001) %MON DXF_min = 3.4932435587116E+03 (PID.TID 0000.0001) %MON DXF_mean = 3.6752948781653E+03 (PID.TID 0000.0001) %MON DXF_sd = 1.0550536922206E+02 (PID.TID 0000.0001) %MON DXG_max = 3.8559871961701E+03 (PID.TID 0000.0001) %MON DXG_min = 3.4923265038643E+03 (PID.TID 0000.0001) %MON DXG_mean = 3.6743811666547E+03 (PID.TID 0000.0001) %MON DXG_sd = 1.0550734153918E+02 (PID.TID 0000.0001) %MON DXV_max = 3.8559871961701E+03 (PID.TID 0000.0001) %MON DXV_min = 3.4923265038643E+03 (PID.TID 0000.0001) %MON DXV_mean = 3.6743811666547E+03 (PID.TID 0000.0001) %MON DXV_sd = 1.0550734153918E+02 (PID.TID 0000.0001) %MON YC_max = -7.3887106250000E+01 (PID.TID 0000.0001) %MON YC_min = -7.5441793750000E+01 (PID.TID 0000.0001) %MON YC_mean = -7.4664450000000E+01 (PID.TID 0000.0001) %MON YC_sd = 4.5104925958293E-01 (PID.TID 0000.0001) %MON YG_max = -7.3891012500000E+01 (PID.TID 0000.0001) %MON YG_min = -7.5445700000000E+01 (PID.TID 0000.0001) %MON YG_mean = -7.4668356250000E+01 (PID.TID 0000.0001) %MON YG_sd = 4.5104925958293E-01 (PID.TID 0000.0001) %MON DYC_max = 8.6857401056280E+02 (PID.TID 0000.0001) %MON DYC_min = 8.6857401056280E+02 (PID.TID 0000.0001) %MON DYC_mean = 8.6857401056280E+02 (PID.TID 0000.0001) %MON DYC_sd = 7.9580786405131E-13 (PID.TID 0000.0001) %MON DYF_max = 8.6857401056280E+02 (PID.TID 0000.0001) %MON DYF_min = 8.6857401056280E+02 (PID.TID 0000.0001) %MON DYF_mean = 8.6857401056280E+02 (PID.TID 0000.0001) %MON DYF_sd = 7.9580786405131E-13 (PID.TID 0000.0001) %MON DYG_max = 8.6857401056280E+02 (PID.TID 0000.0001) %MON DYG_min = 8.6857401056280E+02 (PID.TID 0000.0001) %MON DYG_mean = 8.6857401056280E+02 (PID.TID 0000.0001) %MON DYG_sd = 7.9580786405131E-13 (PID.TID 0000.0001) %MON DYU_max = 8.6857401056280E+02 (PID.TID 0000.0001) %MON DYU_min = 8.6857401056280E+02 (PID.TID 0000.0001) %MON DYU_mean = 8.6857401056280E+02 (PID.TID 0000.0001) %MON DYU_sd = 7.9580786405131E-13 (PID.TID 0000.0001) %MON RA_max = 3.3500008863052E+06 (PID.TID 0000.0001) %MON RA_min = 3.0341405653118E+06 (PID.TID 0000.0001) %MON RA_mean = 3.1922656098560E+06 (PID.TID 0000.0001) %MON RA_sd = 9.1639221610149E+04 (PID.TID 0000.0001) %MON RAW_max = 3.3500008863052E+06 (PID.TID 0000.0001) %MON RAW_min = 3.0341405653118E+06 (PID.TID 0000.0001) %MON RAW_mean = 3.1922656098560E+06 (PID.TID 0000.0001) %MON RAW_sd = 9.1639221610149E+04 (PID.TID 0000.0001) %MON RAS_max = 3.3492102610598E+06 (PID.TID 0000.0001) %MON RAS_min = 3.0333440353089E+06 (PID.TID 0000.0001) %MON RAS_mean = 3.1914719837854E+06 (PID.TID 0000.0001) %MON RAS_sd = 9.1640934713507E+04 (PID.TID 0000.0001) %MON RAZ_max = 3.3492102610598E+06 (PID.TID 0000.0001) %MON RAZ_min = 3.0333440353089E+06 (PID.TID 0000.0001) %MON RAZ_mean = 3.1914719837854E+06 (PID.TID 0000.0001) %MON RAZ_sd = 9.1640934713507E+04 (PID.TID 0000.0001) %MON AngleCS_max = 1.0000000000000E+00 (PID.TID 0000.0001) %MON AngleCS_min = 1.0000000000000E+00 (PID.TID 0000.0001) %MON AngleCS_mean = 1.0000000000000E+00 (PID.TID 0000.0001) %MON AngleCS_sd = 0.0000000000000E+00 (PID.TID 0000.0001) %MON AngleSN_max = 0.0000000000000E+00 (PID.TID 0000.0001) %MON AngleSN_min = 0.0000000000000E+00 (PID.TID 0000.0001) %MON AngleSN_mean = 0.0000000000000E+00 (PID.TID 0000.0001) %MON AngleSN_sd = 0.0000000000000E+00 (PID.TID 0000.0001) GAD_INIT_FIXED: GAD_OlMinSize= 2 0 1 (PID.TID 0000.0001) (PID.TID 0000.0001) // =================================== (PID.TID 0000.0001) // GAD parameters : (PID.TID 0000.0001) // =================================== (PID.TID 0000.0001) tempAdvScheme = /* Temp. Horiz.Advection scheme selector */ (PID.TID 0000.0001) 30 (PID.TID 0000.0001) ; (PID.TID 0000.0001) tempVertAdvScheme = /* Temp. Vert. Advection scheme selector */ (PID.TID 0000.0001) 30 (PID.TID 0000.0001) ; (PID.TID 0000.0001) tempMultiDimAdvec = /* use Muti-Dim Advec method for Temp */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) tempSOM_Advection = /* use 2nd Order Moment Advection for Temp */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) AdamsBashforthGt = /* apply Adams-Bashforth extrapolation on Gt */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) AdamsBashforth_T = /* apply Adams-Bashforth extrapolation on Temp */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) saltAdvScheme = /* Salt. Horiz.advection scheme selector */ (PID.TID 0000.0001) 30 (PID.TID 0000.0001) ; (PID.TID 0000.0001) saltVertAdvScheme = /* Salt. Vert. Advection scheme selector */ (PID.TID 0000.0001) 30 (PID.TID 0000.0001) ; (PID.TID 0000.0001) saltMultiDimAdvec = /* use Muti-Dim Advec method for Salt */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) saltSOM_Advection = /* use 2nd Order Moment Advection for Salt */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) AdamsBashforthGs = /* apply Adams-Bashforth extrapolation on Gs */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) AdamsBashforth_S = /* apply Adams-Bashforth extrapolation on Salt */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) // =================================== (PID.TID 0000.0001) ------------------------------------------------------------ (PID.TID 0000.0001) DIAGNOSTICS_SET_LEVELS: done (PID.TID 0000.0001) Total Nb of available Diagnostics: ndiagt= 197 (PID.TID 0000.0001) write list of available Diagnostics to file: available_diagnostics.log (PID.TID 0000.0001) SETDIAG: Allocate 1 x 1 Levels for Diagnostic # 23 ETAN (PID.TID 0000.0001) SETDIAG: Allocate 1 x 1 Levels for Diagnostic # 79 oceTAUX (PID.TID 0000.0001) SETDIAG: Allocate 1 x 1 Levels for Diagnostic # 80 oceTAUY (PID.TID 0000.0001) SETDIAG: Allocate 1 x 1 Levels for Diagnostic # 85 oceQnet (PID.TID 0000.0001) SETDIAG: Allocate 1 x 1 Levels for Diagnostic # 83 oceFWflx (PID.TID 0000.0001) SETDIAG: Allocate 1 x 1 Levels for Diagnostic # 76 MXLDEPTH (PID.TID 0000.0001) SETDIAG: Allocate 1 x 1 Levels for Diagnostic # 187 SHIfwFlx (PID.TID 0000.0001) SETDIAG: Allocate 1 x 1 Levels for Diagnostic # 188 SHIhtFlx (PID.TID 0000.0001) SETDIAG: Allocate 1 x 1 Levels for Diagnostic # 193 SHIgammT (PID.TID 0000.0001) SETDIAG: Allocate 1 x 1 Levels for Diagnostic # 194 SHIgammS (PID.TID 0000.0001) SETDIAG: Allocate 1 x 1 Levels for Diagnostic # 196 SHI_mass (PID.TID 0000.0001) SETDIAG: Allocate 1 x 1 Levels for Diagnostic # 195 SHIuStar (PID.TID 0000.0001) SETDIAG: Allocate 1 x 1 Levels for Diagnostic # 197 SHI_Rshe (PID.TID 0000.0001) SETDIAG: Allocate100 x 1 Levels for Diagnostic # 30 UVEL (PID.TID 0000.0001) SETDIAG: Allocate100 x 1 Levels for Diagnostic # 31 VVEL (PID.TID 0000.0001) SETDIAG: Allocate100 x 1 Levels for Diagnostic # 32 WVEL (PID.TID 0000.0001) SETDIAG: Allocate100 x 1 Levels for Diagnostic # 26 THETA (PID.TID 0000.0001) SETDIAG: Allocate100 x 1 Levels for Diagnostic # 27 SALT (PID.TID 0000.0001) SETDIAG: Allocate100 x 1 Levels for Diagnostic # 64 RHOAnoma (PID.TID 0000.0001) SETDIAG: Allocate100 x 1 Levels for Diagnostic # 78 CONVADJ (PID.TID 0000.0001) space allocated for all diagnostics: 713 levels (PID.TID 0000.0001) set mate pointer for diag # 79 oceTAUX , Parms: UU U1 , mate: 80 (PID.TID 0000.0001) set mate pointer for diag # 80 oceTAUY , Parms: VV U1 , mate: 79 (PID.TID 0000.0001) set mate pointer for diag # 30 UVEL , Parms: UUR MR , mate: 31 (PID.TID 0000.0001) set mate pointer for diag # 31 VVEL , Parms: VVR MR , mate: 30 (PID.TID 0000.0001) DIAGNOSTICS_SET_POINTERS: Set levels for Outp.Stream: surfDiag (PID.TID 0000.0001) Levels: 1. (PID.TID 0000.0001) DIAGNOSTICS_SET_POINTERS: Set levels for Outp.Stream: dynDiag (PID.TID 0000.0001) Levels: 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. (PID.TID 0000.0001) Levels: 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31. 32. 33. 34. 35. 36. 37. 38. 39. 40. (PID.TID 0000.0001) Levels: 41. 42. 43. 44. 45. 46. 47. 48. 49. 50. 51. 52. 53. 54. 55. 56. 57. 58. 59. 60. (PID.TID 0000.0001) Levels: 61. 62. 63. 64. 65. 66. 67. 68. 69. 70. 71. 72. 73. 74. 75. 76. 77. 78. 79. 80. (PID.TID 0000.0001) Levels: 81. 82. 83. 84. 85. 86. 87. 88. 89. 90. 91. 92. 93. 94. 95. 96. 97. 98. 99. 100. (PID.TID 0000.0001) DIAGNOSTICS_SET_POINTERS: done (PID.TID 0000.0001) ------------------------------------------------------------ (PID.TID 0000.0001) DIAGSTATS_SET_REGIONS: define no region (PID.TID 0000.0001) ------------------------------------------------------------ (PID.TID 0000.0001) space allocated for all stats-diags: 0 levels (PID.TID 0000.0001) DIAGSTATS_SET_POINTERS: done (PID.TID 0000.0001) ------------------------------------------------------------ (PID.TID 0000.0001) %MON fCori_max = 0.0000000000000E+00 (PID.TID 0000.0001) %MON fCori_min = 0.0000000000000E+00 (PID.TID 0000.0001) %MON fCori_mean = 0.0000000000000E+00 (PID.TID 0000.0001) %MON fCori_sd = 0.0000000000000E+00 (PID.TID 0000.0001) %MON fCoriG_max = 0.0000000000000E+00 (PID.TID 0000.0001) %MON fCoriG_min = 0.0000000000000E+00 (PID.TID 0000.0001) %MON fCoriG_mean = 0.0000000000000E+00 (PID.TID 0000.0001) %MON fCoriG_sd = 0.0000000000000E+00 (PID.TID 0000.0001) %MON fCoriCos_max = 0.0000000000000E+00 (PID.TID 0000.0001) %MON fCoriCos_min = 0.0000000000000E+00 (PID.TID 0000.0001) %MON fCoriCos_mean = 0.0000000000000E+00 (PID.TID 0000.0001) %MON fCoriCos_sd = 0.0000000000000E+00 (PID.TID 0000.0001) INI_CG2D: CG2D normalisation factor = 2.2535974547295947E-04 (PID.TID 0000.0001) (PID.TID 0000.0001) // ======================================================= (PID.TID 0000.0001) // Model configuration (PID.TID 0000.0001) // ======================================================= (PID.TID 0000.0001) // (PID.TID 0000.0001) // "Physical" paramters ( PARM01 in namelist ) (PID.TID 0000.0001) // (PID.TID 0000.0001) buoyancyRelation = /* Type of relation to get Buoyancy */ (PID.TID 0000.0001) 'OCEANIC' (PID.TID 0000.0001) ; (PID.TID 0000.0001) fluidIsAir = /* fluid major constituent is Air */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) fluidIsWater = /* fluid major constituent is Water */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) usingPCoords = /* use p (or p*) vertical coordinate */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) usingZCoords = /* use z (or z*) vertical coordinate */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) tRef = /* Reference temperature profile ( oC or K ) */ (PID.TID 0000.0001) 100 @ -1.900000000000000E+00 /* K = 1:100 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) sRef = /* Reference salinity profile ( psu ) */ (PID.TID 0000.0001) 100 @ 3.440000000000000E+01 /* K = 1:100 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) useStrainTensionVisc= /* Use StrainTension Form of Viscous Operator */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) useVariableVisc = /* Use variable horizontal viscosity */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) useHarmonicVisc = /* Use harmonic horizontal viscosity */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) useBiharmonicVisc= /* Use biharmonic horiz. viscosity */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) useSmag3D = /* Use isotropic 3-D Smagorinsky viscosity */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) viscAh = /* Lateral harmonic viscosity ( m^2/s ) */ (PID.TID 0000.0001) 0.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) viscAhMax = /* Maximum lateral harmonic viscosity ( m^2/s ) */ (PID.TID 0000.0001) 1.000000000000000E+21 (PID.TID 0000.0001) ; (PID.TID 0000.0001) viscAhGrid = /* Grid dependent lateral harmonic viscosity ( non-dim. ) */ (PID.TID 0000.0001) 2.000000000000000E-01 (PID.TID 0000.0001) ; (PID.TID 0000.0001) useFullLeith = /* Use Full Form of Leith Viscosity on/off flag*/ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) useAreaViscLength = /* Use area for visc length instead of geom. mean*/ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) viscC2leith = /* Leith harmonic visc. factor (on grad(vort),non-dim.) */ (PID.TID 0000.0001) 0.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) viscC2leithD = /* Leith harmonic viscosity factor (on grad(div),non-dim.)*/ (PID.TID 0000.0001) 0.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) viscC2smag = /* Smagorinsky harmonic viscosity factor (non-dim.) */ (PID.TID 0000.0001) 0.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) viscA4 = /* Lateral biharmonic viscosity ( m^4/s ) */ (PID.TID 0000.0001) 0.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) viscA4Max = /* Maximum biharmonic viscosity ( m^2/s ) */ (PID.TID 0000.0001) 1.000000000000000E+21 (PID.TID 0000.0001) ; (PID.TID 0000.0001) viscA4Grid = /* Grid dependent biharmonic viscosity ( non-dim. ) */ (PID.TID 0000.0001) 2.000000000000000E-02 (PID.TID 0000.0001) ; (PID.TID 0000.0001) viscC4leith = /* Leith biharm viscosity factor (on grad(vort), non-dim.)*/ (PID.TID 0000.0001) 0.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) viscC4leithD = /* Leith biharm viscosity factor (on grad(div), non-dim.) */ (PID.TID 0000.0001) 0.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) viscC4Smag = /* Smagorinsky biharm viscosity factor (non-dim) */ (PID.TID 0000.0001) 0.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) no_slip_sides = /* Viscous BCs: No-slip sides */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) sideDragFactor = /* side-drag scaling factor (non-dim) */ (PID.TID 0000.0001) 2.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) viscArNr = /* vertical profile of vertical viscosity ( m^2/s )*/ (PID.TID 0000.0001) 100 @ 1.000000000000000E-03 /* K = 1:100 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) no_slip_bottom = /* Viscous BCs: No-slip bottom */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) bottomVisc_pCell = /* Partial-cell in bottom Visc. BC */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) bottomDragLinear = /* linear bottom-drag coefficient ( m/s ) */ (PID.TID 0000.0001) 0.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) bottomDragQuadratic = /* quadratic bottom-drag coefficient (-) */ (PID.TID 0000.0001) 2.500000000000000E-03 (PID.TID 0000.0001) ; (PID.TID 0000.0001) selectBotDragQuadr = /* select quadratic bottom drag options */ (PID.TID 0000.0001) 0 (PID.TID 0000.0001) ; (PID.TID 0000.0001) diffKhT = /* Laplacian diffusion of heat laterally ( m^2/s ) */ (PID.TID 0000.0001) 1.000000000000000E+02 (PID.TID 0000.0001) ; (PID.TID 0000.0001) diffK4T = /* Biharmonic diffusion of heat laterally ( m^4/s ) */ (PID.TID 0000.0001) 0.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) diffKhS = /* Laplacian diffusion of salt laterally ( m^2/s ) */ (PID.TID 0000.0001) 1.000000000000000E+02 (PID.TID 0000.0001) ; (PID.TID 0000.0001) diffK4S = /* Biharmonic diffusion of salt laterally ( m^4/s ) */ (PID.TID 0000.0001) 0.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) diffKrNrT = /* vertical profile of vertical diffusion of Temp ( m^2/s )*/ (PID.TID 0000.0001) 100 @ 5.000000000000000E-05 /* K = 1:100 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) diffKrNrS = /* vertical profile of vertical diffusion of Salt ( m^2/s )*/ (PID.TID 0000.0001) 100 @ 5.000000000000000E-05 /* K = 1:100 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) diffKrBL79surf = /* Surface diffusion for Bryan and Lewis 79 ( m^2/s ) */ (PID.TID 0000.0001) 0.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) diffKrBL79deep = /* Deep diffusion for Bryan and Lewis 1979 ( m^2/s ) */ (PID.TID 0000.0001) 0.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) diffKrBL79scl = /* Depth scale for Bryan and Lewis 1979 ( m ) */ (PID.TID 0000.0001) 2.000000000000000E+02 (PID.TID 0000.0001) ; (PID.TID 0000.0001) diffKrBL79Ho = /* Turning depth for Bryan and Lewis 1979 ( m ) */ (PID.TID 0000.0001) -2.000000000000000E+03 (PID.TID 0000.0001) ; (PID.TID 0000.0001) ivdc_kappa = /* Implicit Vertical Diffusivity for Convection ( m^2/s) */ (PID.TID 0000.0001) 0.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) hMixCriteria= /* Criteria for mixed-layer diagnostic */ (PID.TID 0000.0001) -8.000000000000000E-01 (PID.TID 0000.0001) ; (PID.TID 0000.0001) dRhoSmall = /* Parameter for mixed-layer diagnostic */ (PID.TID 0000.0001) 1.000000000000000E-06 (PID.TID 0000.0001) ; (PID.TID 0000.0001) hMixSmooth= /* Smoothing parameter for mixed-layer diagnostic */ (PID.TID 0000.0001) 0.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) eosType = /* Type of Equation of State */ (PID.TID 0000.0001) 'JMD95Z' (PID.TID 0000.0001) ; (PID.TID 0000.0001) HeatCapacity_Cp = /* Specific heat capacity ( J/kg/K ) */ (PID.TID 0000.0001) 3.974000000000000E+03 (PID.TID 0000.0001) ; (PID.TID 0000.0001) celsius2K = /* 0 degree Celsius converted to Kelvin ( K ) */ (PID.TID 0000.0001) 2.731500000000000E+02 (PID.TID 0000.0001) ; (PID.TID 0000.0001) rhoConst = /* Reference density (Boussinesq) ( kg/m^3 ) */ (PID.TID 0000.0001) 1.000000000000000E+03 (PID.TID 0000.0001) ; (PID.TID 0000.0001) rhoFacC = /* normalized Reference density @ cell-Center (-) */ (PID.TID 0000.0001) 100 @ 1.000000000000000E+00 /* K = 1:100 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) rhoFacF = /* normalized Reference density @ W-Interface (-) */ (PID.TID 0000.0001) 101 @ 1.000000000000000E+00 /* K = 1:101 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) rhoConstFresh = /* Fresh-water reference density ( kg/m^3 ) */ (PID.TID 0000.0001) 1.000000000000000E+03 (PID.TID 0000.0001) ; (PID.TID 0000.0001) gravity = /* Gravitational acceleration ( m/s^2 ) */ (PID.TID 0000.0001) 9.810000000000001E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) gBaro = /* Barotropic gravity ( m/s^2 ) */ (PID.TID 0000.0001) 9.810000000000001E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) rotationPeriod = /* Rotation Period ( s ) */ (PID.TID 0000.0001) 8.616400000000000E+04 (PID.TID 0000.0001) ; (PID.TID 0000.0001) omega = /* Angular velocity ( rad/s ) */ (PID.TID 0000.0001) 7.292123516990375E-05 (PID.TID 0000.0001) ; (PID.TID 0000.0001) f0 = /* Reference coriolis parameter ( 1/s ) */ (PID.TID 0000.0001) 0.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) beta = /* Beta ( 1/(m.s) ) */ (PID.TID 0000.0001) 9.999999999999999E-12 (PID.TID 0000.0001) ; (PID.TID 0000.0001) fPrime = /* Second coriolis parameter ( 1/s ) */ (PID.TID 0000.0001) 0.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) rigidLid = /* Rigid lid on/off flag */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) implicitFreeSurface = /* Implicit free surface on/off flag */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) freeSurfFac = /* Implicit free surface factor */ (PID.TID 0000.0001) 1.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) implicSurfPress = /* Surface Pressure implicit factor (0-1)*/ (PID.TID 0000.0001) 1.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) implicDiv2Dflow = /* Barot. Flow Div. implicit factor (0-1)*/ (PID.TID 0000.0001) 1.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) uniformLin_PhiSurf = /* use uniform Bo_surf on/off flag*/ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) uniformFreeSurfLev = /* free-surface level-index is uniform */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) hFacMin = /* minimum partial cell factor (hFac) */ (PID.TID 0000.0001) 2.000000000000000E-01 (PID.TID 0000.0001) ; (PID.TID 0000.0001) hFacMinDr = /* minimum partial cell thickness ( m) */ (PID.TID 0000.0001) 0.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) exactConserv = /* Exact Volume Conservation on/off flag*/ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) linFSConserveTr = /* Tracer correction for Lin Free Surface on/off flag*/ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) nonlinFreeSurf = /* Non-linear Free Surf. options (-1,0,1,2,3)*/ (PID.TID 0000.0001) 4 (PID.TID 0000.0001) -1,0= Off ; 1,2,3= On, 2=+rescale gU,gV, 3=+update cg2d solv. (PID.TID 0000.0001) ; (PID.TID 0000.0001) hFacInf = /* lower threshold for hFac (nonlinFreeSurf only)*/ (PID.TID 0000.0001) 2.000000000000000E-01 (PID.TID 0000.0001) ; (PID.TID 0000.0001) hFacSup = /* upper threshold for hFac (nonlinFreeSurf only)*/ (PID.TID 0000.0001) 2.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) select_rStar = /* r* Vertical coord. options (=0 r coord.; >0 uses r*)*/ (PID.TID 0000.0001) 0 (PID.TID 0000.0001) ; (PID.TID 0000.0001) useRealFreshWaterFlux = /* Real Fresh Water Flux on/off flag*/ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) temp_EvPrRn = /* Temp. of Evap/Prec/R (UNSET=use local T)(oC)*/ (PID.TID 0000.0001) 1.234567000000000E+05 (PID.TID 0000.0001) ; (PID.TID 0000.0001) salt_EvPrRn = /* Salin. of Evap/Prec/R (UNSET=use local S)(psu)*/ (PID.TID 0000.0001) 0.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) selectAddFluid = /* option for mass source/sink of fluid (=0: off) */ (PID.TID 0000.0001) 0 (PID.TID 0000.0001) ; (PID.TID 0000.0001) temp_addMass = /* Temp. of addMass array (UNSET=use local T)(oC)*/ (PID.TID 0000.0001) 1.234567000000000E+05 (PID.TID 0000.0001) ; (PID.TID 0000.0001) salt_addMass = /* Salin. of addMass array (UNSET=use local S)(psu)*/ (PID.TID 0000.0001) 0.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) use3Dsolver = /* use 3-D pressure solver on/off flag */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) nonHydrostatic = /* Non-Hydrostatic on/off flag */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) nh_Am2 = /* Non-Hydrostatic terms scaling factor */ (PID.TID 0000.0001) 1.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) implicitNHPress = /* Non-Hyd Pressure implicit factor (0-1)*/ (PID.TID 0000.0001) 1.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) selectNHfreeSurf = /* Non-Hyd (free-)Surface option */ (PID.TID 0000.0001) 0 (PID.TID 0000.0001) ; (PID.TID 0000.0001) quasiHydrostatic = /* Quasi-Hydrostatic on/off flag */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) calc_wVelocity = /* vertical velocity calculation on/off flag */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) momStepping = /* Momentum equation on/off flag */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) vectorInvariantMomentum= /* Vector-Invariant Momentum on/off */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) momAdvection = /* Momentum advection on/off flag */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) momViscosity = /* Momentum viscosity on/off flag */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) momImplVertAdv= /* Momentum implicit vert. advection on/off*/ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) implicitViscosity = /* Implicit viscosity on/off flag */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) implBottomFriction= /* Implicit bottom friction on/off flag */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) metricTerms = /* metric-Terms on/off flag */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) useNHMTerms = /* Non-Hydrostatic Metric-Terms on/off */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) selectCoriMap = /* Coriolis Map options (0,1,2,3)*/ (PID.TID 0000.0001) 0 (PID.TID 0000.0001) 0= f-Plane ; 1= Beta-Plane ; 2= Spherical ; 3= read from file (PID.TID 0000.0001) ; (PID.TID 0000.0001) use3dCoriolis = /* 3-D Coriolis on/off flag */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) useCoriolis = /* Coriolis on/off flag */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) useCDscheme = /* CD scheme on/off flag */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) useEnergyConservingCoriolis= /* Flx-Form Coriolis scheme flag */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) useJamartWetPoints= /* Coriolis WetPoints method flag */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) useJamartMomAdv= /* V.I Non-linear terms Jamart flag */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) useAbsVorticity= /* V.I Works with f+zeta in Coriolis */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) selectVortScheme= /* V.I Scheme selector for Vorticity-Term */ (PID.TID 0000.0001) 1 (PID.TID 0000.0001) = 0 : enstrophy (Shallow-Water Eq.) conserving scheme by Sadourny, JAS 75 (PID.TID 0000.0001) = 1 : same as 0 with modified hFac (PID.TID 0000.0001) = 2 : energy conserving scheme (used by Sadourny in JAS 75 paper) (PID.TID 0000.0001) = 3 : energy (general) and enstrophy (2D, nonDiv.) conserving scheme (PID.TID 0000.0001) from Sadourny (Burridge & Haseler, ECMWF Rep.4, 1977) (PID.TID 0000.0001) ; (PID.TID 0000.0001) upwindVorticity= /* V.I Upwind bias vorticity flag */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) highOrderVorticity= /* V.I High order vort. advect. flag */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) upwindShear= /* V.I Upwind vertical Shear advection flag */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) selectKEscheme= /* V.I Kinetic Energy scheme selector */ (PID.TID 0000.0001) 0 (PID.TID 0000.0001) ; (PID.TID 0000.0001) momForcing = /* Momentum forcing on/off flag */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) momPressureForcing = /* Momentum pressure term on/off flag */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) implicitIntGravWave= /* Implicit Internal Gravity Wave flag */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) staggerTimeStep = /* Stagger time stepping on/off flag */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) doResetHFactors = /* reset thickness factors @ each time-step */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) multiDimAdvection = /* enable/disable Multi-Dim Advection */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) useMultiDimAdvec = /* Multi-Dim Advection is/is-not used */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) implicitDiffusion = /* Implicit Diffusion on/off flag */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) tempStepping = /* Temperature equation on/off flag */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) tempAdvection = /* Temperature advection on/off flag */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) tempImplVertAdv = /* Temp. implicit vert. advection on/off */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) tempForcing = /* Temperature forcing on/off flag */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) doThetaClimRelax = /* apply SST relaxation on/off flag */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) tempIsActiveTr = /* Temp. is a dynamically Active Tracer */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) saltStepping = /* Salinity equation on/off flag */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) saltAdvection = /* Salinity advection on/off flag */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) saltImplVertAdv = /* Sali. implicit vert. advection on/off */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) saltForcing = /* Salinity forcing on/off flag */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) doSaltClimRelax = /* apply SSS relaxation on/off flag */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) saltIsActiveTr = /* Salt is a dynamically Active Tracer */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) readBinaryPrec = /* Precision used for reading binary files */ (PID.TID 0000.0001) 64 (PID.TID 0000.0001) ; (PID.TID 0000.0001) writeBinaryPrec = /* Precision used for writing binary files */ (PID.TID 0000.0001) 32 (PID.TID 0000.0001) ; (PID.TID 0000.0001) globalFiles = /* write "global" (=not per tile) files */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) useSingleCpuIO = /* only master MPI process does I/O */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) useSingleCpuInput = /* only master process reads input */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) /* debLev[*] : level of debug & auxiliary message printing */ (PID.TID 0000.0001) debLevZero = 0 ; /* level of disabled aux. msg printing */ (PID.TID 0000.0001) debLevA = 1 ; /* level of minimum aux. msg printing */ (PID.TID 0000.0001) debLevB = 2 ; /* level of low aux. print (report read-file opening)*/ (PID.TID 0000.0001) debLevC = 3 ; /* level of moderate debug prt (most pkgs debug msg) */ (PID.TID 0000.0001) debLevD = 4 ; /* level of enhanced debug prt (add DEBUG_STATS prt) */ (PID.TID 0000.0001) debLevE = 5 ; /* level of extensive debug printing */ (PID.TID 0000.0001) debugLevel = /* select debug printing level */ (PID.TID 0000.0001) 1 (PID.TID 0000.0001) ; (PID.TID 0000.0001) // (PID.TID 0000.0001) // Elliptic solver(s) paramters ( PARM02 in namelist ) (PID.TID 0000.0001) // (PID.TID 0000.0001) cg2dMaxIters = /* Upper limit on 2d con. grad iterations */ (PID.TID 0000.0001) 300 (PID.TID 0000.0001) ; (PID.TID 0000.0001) cg2dChkResFreq = /* 2d con. grad convergence test frequency */ (PID.TID 0000.0001) 1 (PID.TID 0000.0001) ; (PID.TID 0000.0001) cg2dUseMinResSol= /* use cg2d last-iter(=0) / min-resid.(=1) solution */ (PID.TID 0000.0001) 0 (PID.TID 0000.0001) ; (PID.TID 0000.0001) cg2dTargetResidual = /* 2d con. grad target residual */ (PID.TID 0000.0001) 9.999999999999999E-12 (PID.TID 0000.0001) ; (PID.TID 0000.0001) cg2dTargetResWunit = /* CG2d target residual [W units] */ (PID.TID 0000.0001) -1.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) cg2dPreCondFreq = /* Freq. for updating cg2d preconditioner */ (PID.TID 0000.0001) 1 (PID.TID 0000.0001) ; (PID.TID 0000.0001) useSRCGSolver = /* use single reduction CG solver(s) */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) printResidualFreq = /* Freq. for printing CG residual */ (PID.TID 0000.0001) 0 (PID.TID 0000.0001) ; (PID.TID 0000.0001) // (PID.TID 0000.0001) // Time stepping paramters ( PARM03 in namelist ) (PID.TID 0000.0001) // (PID.TID 0000.0001) deltaTMom = /* Momentum equation timestep ( s ) */ (PID.TID 0000.0001) 6.000000000000000E+02 (PID.TID 0000.0001) ; (PID.TID 0000.0001) deltaTFreeSurf = /* FreeSurface equation timestep ( s ) */ (PID.TID 0000.0001) 6.000000000000000E+02 (PID.TID 0000.0001) ; (PID.TID 0000.0001) dTtracerLev = /* Tracer equation timestep ( s ) */ (PID.TID 0000.0001) 100 @ 6.000000000000000E+02 /* K = 1:100 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) deltaTClock = /* Model clock timestep ( s ) */ (PID.TID 0000.0001) 6.000000000000000E+02 (PID.TID 0000.0001) ; (PID.TID 0000.0001) cAdjFreq = /* Convective adjustment interval ( s ) */ (PID.TID 0000.0001) 6.000000000000000E+02 (PID.TID 0000.0001) ; (PID.TID 0000.0001) momForcingOutAB = /* =1: take Momentum Forcing out of Adams-Bash. stepping */ (PID.TID 0000.0001) 1 (PID.TID 0000.0001) ; (PID.TID 0000.0001) tracForcingOutAB = /* =1: take T,S,pTr Forcing out of Adams-Bash. stepping */ (PID.TID 0000.0001) 1 (PID.TID 0000.0001) ; (PID.TID 0000.0001) momDissip_In_AB = /* put Dissipation Tendency in Adams-Bash. stepping */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) doAB_onGtGs = /* apply AB on Tendencies (rather than on T,S)*/ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) abEps = /* Adams-Bashforth-2 stabilizing weight */ (PID.TID 0000.0001) 1.000000000000000E-01 (PID.TID 0000.0001) ; (PID.TID 0000.0001) pickupStrictlyMatch= /* stop if pickup do not strictly match */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) nIter0 = /* Run starting timestep number */ (PID.TID 0000.0001) 4320 (PID.TID 0000.0001) ; (PID.TID 0000.0001) nTimeSteps = /* Number of timesteps */ (PID.TID 0000.0001) 10 (PID.TID 0000.0001) ; (PID.TID 0000.0001) nEndIter = /* Run ending timestep number */ (PID.TID 0000.0001) 4330 (PID.TID 0000.0001) ; (PID.TID 0000.0001) baseTime = /* Model base time ( s ) */ (PID.TID 0000.0001) 0.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) startTime = /* Run start time ( s ) */ (PID.TID 0000.0001) 2.592000000000000E+06 (PID.TID 0000.0001) ; (PID.TID 0000.0001) endTime = /* Integration ending time ( s ) */ (PID.TID 0000.0001) 2.598000000000000E+06 (PID.TID 0000.0001) ; (PID.TID 0000.0001) pChkPtFreq = /* Permanent restart/pickup file interval ( s ) */ (PID.TID 0000.0001) 2.592000000000000E+06 (PID.TID 0000.0001) ; (PID.TID 0000.0001) chkPtFreq = /* Rolling restart/pickup file interval ( s ) */ (PID.TID 0000.0001) 2.592000000000000E+06 (PID.TID 0000.0001) ; (PID.TID 0000.0001) pickup_write_mdsio = /* Model IO flag. */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) pickup_read_mdsio = /* Model IO flag. */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) pickup_write_immed = /* Model IO flag. */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) writePickupAtEnd = /* Model IO flag. */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) dumpFreq = /* Model state write out interval ( s ). */ (PID.TID 0000.0001) 2.592000000000000E+06 (PID.TID 0000.0001) ; (PID.TID 0000.0001) dumpInitAndLast= /* write out Initial & Last iter. model state */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) snapshot_mdsio = /* Model IO flag. */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) monitorFreq = /* Monitor output interval ( s ). */ (PID.TID 0000.0001) 2.592000000000000E+06 (PID.TID 0000.0001) ; (PID.TID 0000.0001) monitorSelect = /* select group of variables to monitor */ (PID.TID 0000.0001) 3 (PID.TID 0000.0001) ; (PID.TID 0000.0001) monitor_stdio = /* Model IO flag. */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) externForcingPeriod = /* forcing period (s) */ (PID.TID 0000.0001) 0.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) externForcingCycle = /* period of the cyle (s). */ (PID.TID 0000.0001) 0.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) tauThetaClimRelax = /* relaxation time scale (s) */ (PID.TID 0000.0001) 0.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) tauSaltClimRelax = /* relaxation time scale (s) */ (PID.TID 0000.0001) 0.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) latBandClimRelax = /* max. Lat. where relaxation */ (PID.TID 0000.0001) 1.800000000000000E+02 (PID.TID 0000.0001) ; (PID.TID 0000.0001) // (PID.TID 0000.0001) // Gridding paramters ( PARM04 in namelist ) (PID.TID 0000.0001) // (PID.TID 0000.0001) usingCartesianGrid = /* Cartesian coordinates flag ( True/False ) */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) usingCylindricalGrid = /* Cylindrical coordinates flag ( True/False ) */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) usingSphericalPolarGrid = /* Spherical coordinates flag ( True/False ) */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) usingCurvilinearGrid = /* Curvilinear coordinates flag ( True/False ) */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) selectSigmaCoord = /* Hybrid-Sigma Vert. Coordinate option */ (PID.TID 0000.0001) 0 (PID.TID 0000.0001) ; (PID.TID 0000.0001) Ro_SeaLevel = /* r(1) ( units of r == m ) */ (PID.TID 0000.0001) 0.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) rSigmaBnd = /* r/sigma transition ( units of r == m ) */ (PID.TID 0000.0001) 1.234567000000000E+05 (PID.TID 0000.0001) ; (PID.TID 0000.0001) rkSign = /* index orientation relative to vertical coordinate */ (PID.TID 0000.0001) -1.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) gravitySign = /* gravity orientation relative to vertical coordinate */ (PID.TID 0000.0001) -1.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) mass2rUnit = /* convert mass per unit area [kg/m2] to r-units [m] */ (PID.TID 0000.0001) 1.000000000000000E-03 (PID.TID 0000.0001) ; (PID.TID 0000.0001) rUnit2mass = /* convert r-units [m] to mass per unit area [kg/m2] */ (PID.TID 0000.0001) 1.000000000000000E+03 (PID.TID 0000.0001) ; (PID.TID 0000.0001) drC = /* C spacing ( units of r ) */ (PID.TID 0000.0001) 5.000000000000000E+00, /* K = 1 */ (PID.TID 0000.0001) 99 @ 1.000000000000000E+01, /* K = 2:100 */ (PID.TID 0000.0001) 5.000000000000000E+00 /* K =101 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) drF = /* W spacing ( units of r ) */ (PID.TID 0000.0001) 100 @ 1.000000000000000E+01 /* K = 1:100 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) delX = /* U spacing ( m - cartesian, degrees - spherical ) */ (PID.TID 0000.0001) 1.250000000000000E-01 /* I = 1 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) delY = /* V spacing ( m - cartesian, degrees - spherical ) */ (PID.TID 0000.0001) 200 @ 7.812500000000000E-03 /* J = 1:200 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) xgOrigin = /* X-axis origin of West edge (cartesian: m, lat-lon: deg) */ (PID.TID 0000.0001) -1.055000000000000E+02 (PID.TID 0000.0001) ; (PID.TID 0000.0001) ygOrigin = /* Y-axis origin of South edge (cartesian: m, lat-lon: deg) */ (PID.TID 0000.0001) -7.544570000000000E+01 (PID.TID 0000.0001) ; (PID.TID 0000.0001) rSphere = /* Radius ( ignored - cartesian, m - spherical ) */ (PID.TID 0000.0001) 6.370000000000000E+06 (PID.TID 0000.0001) ; (PID.TID 0000.0001) deepAtmosphere = /* Deep/Shallow Atmosphere flag (True/False) */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) xC = /* xC(:,1,:,1) : P-point X coord ( deg. or m if cartesian) */ (PID.TID 0000.0001) -1.054375000000000E+02 /* I = 1 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) yC = /* yC(1,:,1,:) : P-point Y coord ( deg. or m if cartesian) */ (PID.TID 0000.0001) -7.544179375000000E+01, /* J = 1 */ (PID.TID 0000.0001) -7.543398125000000E+01, /* J = 2 */ (PID.TID 0000.0001) -7.542616875000000E+01, /* J = 3 */ (PID.TID 0000.0001) . . . (PID.TID 0000.0001) -7.507460625000000E+01, /* J = 48 */ (PID.TID 0000.0001) -7.506679375000000E+01, /* J = 49 */ (PID.TID 0000.0001) -7.505898125000000E+01, /* J = 50 */ (PID.TID 0000.0001) -7.505116875000000E+01, /* J = 51 */ (PID.TID 0000.0001) -7.504335625000000E+01, /* J = 52 */ (PID.TID 0000.0001) -7.503554375000000E+01, /* J = 53 */ (PID.TID 0000.0001) . . . (PID.TID 0000.0001) -7.468398125000000E+01, /* J = 98 */ (PID.TID 0000.0001) -7.467616875000000E+01, /* J = 99 */ (PID.TID 0000.0001) -7.466835625000000E+01, /* J =100 */ (PID.TID 0000.0001) -7.466054375000000E+01, /* J =101 */ (PID.TID 0000.0001) -7.465273125000000E+01, /* J =102 */ (PID.TID 0000.0001) -7.464491875000000E+01, /* J =103 */ (PID.TID 0000.0001) . . . (PID.TID 0000.0001) -7.429335625000000E+01, /* J =148 */ (PID.TID 0000.0001) -7.428554375000000E+01, /* J =149 */ (PID.TID 0000.0001) -7.427773125000000E+01, /* J =150 */ (PID.TID 0000.0001) -7.426991875000000E+01, /* J =151 */ (PID.TID 0000.0001) -7.426210625000000E+01, /* J =152 */ (PID.TID 0000.0001) -7.425429375000000E+01, /* J =153 */ (PID.TID 0000.0001) . . . (PID.TID 0000.0001) -7.390273125000000E+01, /* J =198 */ (PID.TID 0000.0001) -7.389491875000000E+01, /* J =199 */ (PID.TID 0000.0001) -7.388710625000000E+01 /* J =200 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) rcoord = /* P-point R coordinate ( units of r ) */ (PID.TID 0000.0001) -5.000000000000000E+00, /* K = 1 */ (PID.TID 0000.0001) -1.500000000000000E+01, /* K = 2 */ (PID.TID 0000.0001) -2.500000000000000E+01, /* K = 3 */ (PID.TID 0000.0001) -3.500000000000000E+01, /* K = 4 */ (PID.TID 0000.0001) -4.500000000000000E+01, /* K = 5 */ (PID.TID 0000.0001) -5.500000000000000E+01, /* K = 6 */ (PID.TID 0000.0001) -6.500000000000000E+01, /* K = 7 */ (PID.TID 0000.0001) -7.500000000000000E+01, /* K = 8 */ (PID.TID 0000.0001) -8.500000000000000E+01, /* K = 9 */ (PID.TID 0000.0001) -9.500000000000000E+01, /* K = 10 */ (PID.TID 0000.0001) -1.050000000000000E+02, /* K = 11 */ (PID.TID 0000.0001) -1.150000000000000E+02, /* K = 12 */ (PID.TID 0000.0001) -1.250000000000000E+02, /* K = 13 */ (PID.TID 0000.0001) -1.350000000000000E+02, /* K = 14 */ (PID.TID 0000.0001) -1.450000000000000E+02, /* K = 15 */ (PID.TID 0000.0001) -1.550000000000000E+02, /* K = 16 */ (PID.TID 0000.0001) -1.650000000000000E+02, /* K = 17 */ (PID.TID 0000.0001) -1.750000000000000E+02, /* K = 18 */ (PID.TID 0000.0001) -1.850000000000000E+02, /* K = 19 */ (PID.TID 0000.0001) -1.950000000000000E+02, /* K = 20 */ (PID.TID 0000.0001) -2.050000000000000E+02, /* K = 21 */ (PID.TID 0000.0001) -2.150000000000000E+02, /* K = 22 */ (PID.TID 0000.0001) -2.250000000000000E+02, /* K = 23 */ (PID.TID 0000.0001) -2.350000000000000E+02, /* K = 24 */ (PID.TID 0000.0001) -2.450000000000000E+02, /* K = 25 */ (PID.TID 0000.0001) -2.550000000000000E+02, /* K = 26 */ (PID.TID 0000.0001) -2.650000000000000E+02, /* K = 27 */ (PID.TID 0000.0001) -2.750000000000000E+02, /* K = 28 */ (PID.TID 0000.0001) -2.850000000000000E+02, /* K = 29 */ (PID.TID 0000.0001) -2.950000000000000E+02, /* K = 30 */ (PID.TID 0000.0001) -3.050000000000000E+02, /* K = 31 */ (PID.TID 0000.0001) -3.150000000000000E+02, /* K = 32 */ (PID.TID 0000.0001) -3.250000000000000E+02, /* K = 33 */ (PID.TID 0000.0001) -3.350000000000000E+02, /* K = 34 */ (PID.TID 0000.0001) -3.450000000000000E+02, /* K = 35 */ (PID.TID 0000.0001) -3.550000000000000E+02, /* K = 36 */ (PID.TID 0000.0001) -3.650000000000000E+02, /* K = 37 */ (PID.TID 0000.0001) -3.750000000000000E+02, /* K = 38 */ (PID.TID 0000.0001) -3.850000000000000E+02, /* K = 39 */ (PID.TID 0000.0001) -3.950000000000000E+02, /* K = 40 */ (PID.TID 0000.0001) -4.050000000000000E+02, /* K = 41 */ (PID.TID 0000.0001) -4.150000000000000E+02, /* K = 42 */ (PID.TID 0000.0001) -4.250000000000000E+02, /* K = 43 */ (PID.TID 0000.0001) -4.350000000000000E+02, /* K = 44 */ (PID.TID 0000.0001) -4.450000000000000E+02, /* K = 45 */ (PID.TID 0000.0001) -4.550000000000000E+02, /* K = 46 */ (PID.TID 0000.0001) -4.650000000000000E+02, /* K = 47 */ (PID.TID 0000.0001) -4.750000000000000E+02, /* K = 48 */ (PID.TID 0000.0001) -4.850000000000000E+02, /* K = 49 */ (PID.TID 0000.0001) -4.950000000000000E+02, /* K = 50 */ (PID.TID 0000.0001) -5.050000000000000E+02, /* K = 51 */ (PID.TID 0000.0001) -5.150000000000000E+02, /* K = 52 */ (PID.TID 0000.0001) -5.250000000000000E+02, /* K = 53 */ (PID.TID 0000.0001) -5.350000000000000E+02, /* K = 54 */ (PID.TID 0000.0001) -5.450000000000000E+02, /* K = 55 */ (PID.TID 0000.0001) -5.550000000000000E+02, /* K = 56 */ (PID.TID 0000.0001) -5.650000000000000E+02, /* K = 57 */ (PID.TID 0000.0001) -5.750000000000000E+02, /* K = 58 */ (PID.TID 0000.0001) -5.850000000000000E+02, /* K = 59 */ (PID.TID 0000.0001) -5.950000000000000E+02, /* K = 60 */ (PID.TID 0000.0001) -6.050000000000000E+02, /* K = 61 */ (PID.TID 0000.0001) -6.150000000000000E+02, /* K = 62 */ (PID.TID 0000.0001) -6.250000000000000E+02, /* K = 63 */ (PID.TID 0000.0001) -6.350000000000000E+02, /* K = 64 */ (PID.TID 0000.0001) -6.450000000000000E+02, /* K = 65 */ (PID.TID 0000.0001) -6.550000000000000E+02, /* K = 66 */ (PID.TID 0000.0001) -6.650000000000000E+02, /* K = 67 */ (PID.TID 0000.0001) -6.750000000000000E+02, /* K = 68 */ (PID.TID 0000.0001) -6.850000000000000E+02, /* K = 69 */ (PID.TID 0000.0001) -6.950000000000000E+02, /* K = 70 */ (PID.TID 0000.0001) -7.050000000000000E+02, /* K = 71 */ (PID.TID 0000.0001) -7.150000000000000E+02, /* K = 72 */ (PID.TID 0000.0001) -7.250000000000000E+02, /* K = 73 */ (PID.TID 0000.0001) -7.350000000000000E+02, /* K = 74 */ (PID.TID 0000.0001) -7.450000000000000E+02, /* K = 75 */ (PID.TID 0000.0001) -7.550000000000000E+02, /* K = 76 */ (PID.TID 0000.0001) -7.650000000000000E+02, /* K = 77 */ (PID.TID 0000.0001) -7.750000000000000E+02, /* K = 78 */ (PID.TID 0000.0001) -7.850000000000000E+02, /* K = 79 */ (PID.TID 0000.0001) -7.950000000000000E+02, /* K = 80 */ (PID.TID 0000.0001) -8.050000000000000E+02, /* K = 81 */ (PID.TID 0000.0001) -8.150000000000000E+02, /* K = 82 */ (PID.TID 0000.0001) -8.250000000000000E+02, /* K = 83 */ (PID.TID 0000.0001) -8.350000000000000E+02, /* K = 84 */ (PID.TID 0000.0001) -8.450000000000000E+02, /* K = 85 */ (PID.TID 0000.0001) -8.550000000000000E+02, /* K = 86 */ (PID.TID 0000.0001) -8.650000000000000E+02, /* K = 87 */ (PID.TID 0000.0001) -8.750000000000000E+02, /* K = 88 */ (PID.TID 0000.0001) -8.850000000000000E+02, /* K = 89 */ (PID.TID 0000.0001) -8.950000000000000E+02, /* K = 90 */ (PID.TID 0000.0001) -9.050000000000000E+02, /* K = 91 */ (PID.TID 0000.0001) -9.150000000000000E+02, /* K = 92 */ (PID.TID 0000.0001) -9.250000000000000E+02, /* K = 93 */ (PID.TID 0000.0001) -9.350000000000000E+02, /* K = 94 */ (PID.TID 0000.0001) -9.450000000000000E+02, /* K = 95 */ (PID.TID 0000.0001) -9.550000000000000E+02, /* K = 96 */ (PID.TID 0000.0001) -9.650000000000000E+02, /* K = 97 */ (PID.TID 0000.0001) -9.750000000000000E+02, /* K = 98 */ (PID.TID 0000.0001) -9.850000000000000E+02, /* K = 99 */ (PID.TID 0000.0001) -9.950000000000000E+02 /* K =100 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) rF = /* W-Interf. R coordinate ( units of r ) */ (PID.TID 0000.0001) 0.000000000000000E+00, /* K = 1 */ (PID.TID 0000.0001) -1.000000000000000E+01, /* K = 2 */ (PID.TID 0000.0001) -2.000000000000000E+01, /* K = 3 */ (PID.TID 0000.0001) -3.000000000000000E+01, /* K = 4 */ (PID.TID 0000.0001) -4.000000000000000E+01, /* K = 5 */ (PID.TID 0000.0001) -5.000000000000000E+01, /* K = 6 */ (PID.TID 0000.0001) -6.000000000000000E+01, /* K = 7 */ (PID.TID 0000.0001) -7.000000000000000E+01, /* K = 8 */ (PID.TID 0000.0001) -8.000000000000000E+01, /* K = 9 */ (PID.TID 0000.0001) -9.000000000000000E+01, /* K = 10 */ (PID.TID 0000.0001) -1.000000000000000E+02, /* K = 11 */ (PID.TID 0000.0001) -1.100000000000000E+02, /* K = 12 */ (PID.TID 0000.0001) -1.200000000000000E+02, /* K = 13 */ (PID.TID 0000.0001) -1.300000000000000E+02, /* K = 14 */ (PID.TID 0000.0001) -1.400000000000000E+02, /* K = 15 */ (PID.TID 0000.0001) -1.500000000000000E+02, /* K = 16 */ (PID.TID 0000.0001) -1.600000000000000E+02, /* K = 17 */ (PID.TID 0000.0001) -1.700000000000000E+02, /* K = 18 */ (PID.TID 0000.0001) -1.800000000000000E+02, /* K = 19 */ (PID.TID 0000.0001) -1.900000000000000E+02, /* K = 20 */ (PID.TID 0000.0001) -2.000000000000000E+02, /* K = 21 */ (PID.TID 0000.0001) -2.100000000000000E+02, /* K = 22 */ (PID.TID 0000.0001) -2.200000000000000E+02, /* K = 23 */ (PID.TID 0000.0001) -2.300000000000000E+02, /* K = 24 */ (PID.TID 0000.0001) -2.400000000000000E+02, /* K = 25 */ (PID.TID 0000.0001) -2.500000000000000E+02, /* K = 26 */ (PID.TID 0000.0001) -2.600000000000000E+02, /* K = 27 */ (PID.TID 0000.0001) -2.700000000000000E+02, /* K = 28 */ (PID.TID 0000.0001) -2.800000000000000E+02, /* K = 29 */ (PID.TID 0000.0001) -2.900000000000000E+02, /* K = 30 */ (PID.TID 0000.0001) -3.000000000000000E+02, /* K = 31 */ (PID.TID 0000.0001) -3.100000000000000E+02, /* K = 32 */ (PID.TID 0000.0001) -3.200000000000000E+02, /* K = 33 */ (PID.TID 0000.0001) -3.300000000000000E+02, /* K = 34 */ (PID.TID 0000.0001) -3.400000000000000E+02, /* K = 35 */ (PID.TID 0000.0001) -3.500000000000000E+02, /* K = 36 */ (PID.TID 0000.0001) -3.600000000000000E+02, /* K = 37 */ (PID.TID 0000.0001) -3.700000000000000E+02, /* K = 38 */ (PID.TID 0000.0001) -3.800000000000000E+02, /* K = 39 */ (PID.TID 0000.0001) -3.900000000000000E+02, /* K = 40 */ (PID.TID 0000.0001) -4.000000000000000E+02, /* K = 41 */ (PID.TID 0000.0001) -4.100000000000000E+02, /* K = 42 */ (PID.TID 0000.0001) -4.200000000000000E+02, /* K = 43 */ (PID.TID 0000.0001) -4.300000000000000E+02, /* K = 44 */ (PID.TID 0000.0001) -4.400000000000000E+02, /* K = 45 */ (PID.TID 0000.0001) -4.500000000000000E+02, /* K = 46 */ (PID.TID 0000.0001) -4.600000000000000E+02, /* K = 47 */ (PID.TID 0000.0001) -4.700000000000000E+02, /* K = 48 */ (PID.TID 0000.0001) -4.800000000000000E+02, /* K = 49 */ (PID.TID 0000.0001) -4.900000000000000E+02, /* K = 50 */ (PID.TID 0000.0001) -5.000000000000000E+02, /* K = 51 */ (PID.TID 0000.0001) -5.100000000000000E+02, /* K = 52 */ (PID.TID 0000.0001) -5.200000000000000E+02, /* K = 53 */ (PID.TID 0000.0001) -5.300000000000000E+02, /* K = 54 */ (PID.TID 0000.0001) -5.400000000000000E+02, /* K = 55 */ (PID.TID 0000.0001) -5.500000000000000E+02, /* K = 56 */ (PID.TID 0000.0001) -5.600000000000000E+02, /* K = 57 */ (PID.TID 0000.0001) -5.700000000000000E+02, /* K = 58 */ (PID.TID 0000.0001) -5.800000000000000E+02, /* K = 59 */ (PID.TID 0000.0001) -5.900000000000000E+02, /* K = 60 */ (PID.TID 0000.0001) -6.000000000000000E+02, /* K = 61 */ (PID.TID 0000.0001) -6.100000000000000E+02, /* K = 62 */ (PID.TID 0000.0001) -6.200000000000000E+02, /* K = 63 */ (PID.TID 0000.0001) -6.300000000000000E+02, /* K = 64 */ (PID.TID 0000.0001) -6.400000000000000E+02, /* K = 65 */ (PID.TID 0000.0001) -6.500000000000000E+02, /* K = 66 */ (PID.TID 0000.0001) -6.600000000000000E+02, /* K = 67 */ (PID.TID 0000.0001) -6.700000000000000E+02, /* K = 68 */ (PID.TID 0000.0001) -6.800000000000000E+02, /* K = 69 */ (PID.TID 0000.0001) -6.900000000000000E+02, /* K = 70 */ (PID.TID 0000.0001) -7.000000000000000E+02, /* K = 71 */ (PID.TID 0000.0001) -7.100000000000000E+02, /* K = 72 */ (PID.TID 0000.0001) -7.200000000000000E+02, /* K = 73 */ (PID.TID 0000.0001) -7.300000000000000E+02, /* K = 74 */ (PID.TID 0000.0001) -7.400000000000000E+02, /* K = 75 */ (PID.TID 0000.0001) -7.500000000000000E+02, /* K = 76 */ (PID.TID 0000.0001) -7.600000000000000E+02, /* K = 77 */ (PID.TID 0000.0001) -7.700000000000000E+02, /* K = 78 */ (PID.TID 0000.0001) -7.800000000000000E+02, /* K = 79 */ (PID.TID 0000.0001) -7.900000000000000E+02, /* K = 80 */ (PID.TID 0000.0001) -8.000000000000000E+02, /* K = 81 */ (PID.TID 0000.0001) -8.100000000000000E+02, /* K = 82 */ (PID.TID 0000.0001) -8.200000000000000E+02, /* K = 83 */ (PID.TID 0000.0001) -8.300000000000000E+02, /* K = 84 */ (PID.TID 0000.0001) -8.400000000000000E+02, /* K = 85 */ (PID.TID 0000.0001) -8.500000000000000E+02, /* K = 86 */ (PID.TID 0000.0001) -8.600000000000000E+02, /* K = 87 */ (PID.TID 0000.0001) -8.700000000000000E+02, /* K = 88 */ (PID.TID 0000.0001) -8.800000000000000E+02, /* K = 89 */ (PID.TID 0000.0001) -8.900000000000000E+02, /* K = 90 */ (PID.TID 0000.0001) -9.000000000000000E+02, /* K = 91 */ (PID.TID 0000.0001) -9.100000000000000E+02, /* K = 92 */ (PID.TID 0000.0001) -9.200000000000000E+02, /* K = 93 */ (PID.TID 0000.0001) -9.300000000000000E+02, /* K = 94 */ (PID.TID 0000.0001) -9.400000000000000E+02, /* K = 95 */ (PID.TID 0000.0001) -9.500000000000000E+02, /* K = 96 */ (PID.TID 0000.0001) -9.600000000000000E+02, /* K = 97 */ (PID.TID 0000.0001) -9.700000000000000E+02, /* K = 98 */ (PID.TID 0000.0001) -9.800000000000000E+02, /* K = 99 */ (PID.TID 0000.0001) -9.900000000000000E+02, /* K =100 */ (PID.TID 0000.0001) -1.000000000000000E+03 /* K =101 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) deepFacC = /* deep-model grid factor @ cell-Center (-) */ (PID.TID 0000.0001) 100 @ 1.000000000000000E+00 /* K = 1:100 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) deepFacF = /* deep-model grid factor @ W-Interface (-) */ (PID.TID 0000.0001) 101 @ 1.000000000000000E+00 /* K = 1:101 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) rVel2wUnit = /* convert units: rVel -> wSpeed (=1 if z-coord)*/ (PID.TID 0000.0001) 101 @ 1.000000000000000E+00 /* K = 1:101 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) wUnit2rVel = /* convert units: wSpeed -> rVel (=1 if z-coord)*/ (PID.TID 0000.0001) 101 @ 1.000000000000000E+00 /* K = 1:101 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) dBdrRef = /* Vertical grad. of reference buoyancy [(m/s/r)^2] */ (PID.TID 0000.0001) 100 @ 0.000000000000000E+00 /* K = 1:100 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) rotateGrid = /* use rotated grid ( True/False ) */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) phiEuler = /* Euler angle, rotation about original z-coordinate [rad] */ (PID.TID 0000.0001) 0.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) thetaEuler = /* Euler angle, rotation about new x-coordinate [rad] */ (PID.TID 0000.0001) 0.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) psiEuler = /* Euler angle, rotation about new z-coordinate [rad] */ (PID.TID 0000.0001) 0.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) dxF = /* dxF(:,1,:,1) ( units: m ) */ (PID.TID 0000.0001) 3.493243558711626E+03 /* I = 1 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) dxF = /* dxF(1,:,1,:) ( units: m ) */ (PID.TID 0000.0001) 3.493243558711626E+03, /* J = 1 */ (PID.TID 0000.0001) 3.495077619691311E+03, /* J = 2 */ (PID.TID 0000.0001) 3.496911615689215E+03, /* J = 3 */ (PID.TID 0000.0001) . . . (PID.TID 0000.0001) 3.579373626761998E+03, /* J = 48 */ (PID.TID 0000.0001) 3.581204596757318E+03, /* J = 49 */ (PID.TID 0000.0001) 3.583035500169550E+03, /* J = 50 */ (PID.TID 0000.0001) 3.584866336964656E+03, /* J = 51 */ (PID.TID 0000.0001) 3.586697107108589E+03, /* J = 52 */ (PID.TID 0000.0001) 3.588527810567320E+03, /* J = 53 */ (PID.TID 0000.0001) . . . (PID.TID 0000.0001) 3.670839895332228E+03, /* J = 98 */ (PID.TID 0000.0001) 3.672667494497579E+03, /* J = 99 */ (PID.TID 0000.0001) 3.674495025379331E+03, /* J =100 */ (PID.TID 0000.0001) 3.676322487943506E+03, /* J =101 */ (PID.TID 0000.0001) 3.678149882156126E+03, /* J =102 */ (PID.TID 0000.0001) 3.679977207983216E+03, /* J =103 */ (PID.TID 0000.0001) . . . (PID.TID 0000.0001) 3.762135540512856E+03, /* J =148 */ (PID.TID 0000.0001) 3.763959683900060E+03, /* J =149 */ (PID.TID 0000.0001) 3.765783757306327E+03, /* J =150 */ (PID.TID 0000.0001) 3.767607760697741E+03, /* J =151 */ (PID.TID 0000.0001) 3.769431694040391E+03, /* J =152 */ (PID.TID 0000.0001) 3.771255557300366E+03, /* J =153 */ (PID.TID 0000.0001) . . . (PID.TID 0000.0001) 3.853256318813865E+03, /* J =198 */ (PID.TID 0000.0001) 3.855076921635369E+03, /* J =199 */ (PID.TID 0000.0001) 3.856897452781851E+03 /* J =200 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) dyF = /* dyF(:,1,:,1) ( units: m ) */ (PID.TID 0000.0001) 8.685740105628031E+02 /* I = 1 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) dyF = /* dyF(1,:,1,:) ( units: m ) */ (PID.TID 0000.0001) 200 @ 8.685740105628031E+02 /* J = 1:200 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) dxG = /* dxG(:,1,:,1) ( units: m ) */ (PID.TID 0000.0001) 3.492326503864269E+03 /* I = 1 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) dxG = /* dxG(1,:,1,:) ( units: m ) */ (PID.TID 0000.0001) 3.492326503864269E+03, /* J = 1 */ (PID.TID 0000.0001) 3.494160597322059E+03, /* J = 2 */ (PID.TID 0000.0001) 3.495994625815115E+03, /* J = 3 */ (PID.TID 0000.0001) . . . (PID.TID 0000.0001) 3.578458116806316E+03, /* J = 48 */ (PID.TID 0000.0001) 3.580289120080414E+03, /* J = 49 */ (PID.TID 0000.0001) 3.582120056788447E+03, /* J = 50 */ (PID.TID 0000.0001) 3.583950926896370E+03, /* J = 51 */ (PID.TID 0000.0001) 3.585781730370146E+03, /* J = 52 */ (PID.TID 0000.0001) 3.587612467175734E+03, /* J = 53 */ (PID.TID 0000.0001) . . . (PID.TID 0000.0001) 3.669926070153822E+03, /* J = 98 */ (PID.TID 0000.0001) 3.671753703448232E+03, /* J = 99 */ (PID.TID 0000.0001) 3.673581268476031E+03, /* J =100 */ (PID.TID 0000.0001) 3.675408765203241E+03, /* J =101 */ (PID.TID 0000.0001) 3.677236193595885E+03, /* J =102 */ (PID.TID 0000.0001) 3.679063553619987E+03, /* J =103 */ (PID.TID 0000.0001) . . . (PID.TID 0000.0001) 3.761223442587002E+03, /* J =148 */ (PID.TID 0000.0001) 3.763047620951957E+03, /* J =149 */ (PID.TID 0000.0001) 3.764871729352929E+03, /* J =150 */ (PID.TID 0000.0001) 3.766695767756008E+03, /* J =151 */ (PID.TID 0000.0001) 3.768519736127280E+03, /* J =152 */ (PID.TID 0000.0001) 3.770343634432832E+03, /* J =153 */ (PID.TID 0000.0001) . . . (PID.TID 0000.0001) 3.852345990535555E+03, /* J =198 */ (PID.TID 0000.0001) 3.854166629181878E+03, /* J =199 */ (PID.TID 0000.0001) 3.855987196170102E+03 /* J =200 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) dyG = /* dyG(:,1,:,1) ( units: m ) */ (PID.TID 0000.0001) 8.685740105628031E+02 /* I = 1 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) dyG = /* dyG(1,:,1,:) ( units: m ) */ (PID.TID 0000.0001) 200 @ 8.685740105628031E+02 /* J = 1:200 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) dxC = /* dxC(:,1,:,1) ( units: m ) */ (PID.TID 0000.0001) 3.493243558711626E+03 /* I = 1 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) dxC = /* dxC(1,:,1,:) ( units: m ) */ (PID.TID 0000.0001) 3.493243558711626E+03, /* J = 1 */ (PID.TID 0000.0001) 3.495077619691311E+03, /* J = 2 */ (PID.TID 0000.0001) 3.496911615689215E+03, /* J = 3 */ (PID.TID 0000.0001) . . . (PID.TID 0000.0001) 3.579373626761998E+03, /* J = 48 */ (PID.TID 0000.0001) 3.581204596757318E+03, /* J = 49 */ (PID.TID 0000.0001) 3.583035500169550E+03, /* J = 50 */ (PID.TID 0000.0001) 3.584866336964656E+03, /* J = 51 */ (PID.TID 0000.0001) 3.586697107108589E+03, /* J = 52 */ (PID.TID 0000.0001) 3.588527810567320E+03, /* J = 53 */ (PID.TID 0000.0001) . . . (PID.TID 0000.0001) 3.670839895332228E+03, /* J = 98 */ (PID.TID 0000.0001) 3.672667494497579E+03, /* J = 99 */ (PID.TID 0000.0001) 3.674495025379331E+03, /* J =100 */ (PID.TID 0000.0001) 3.676322487943506E+03, /* J =101 */ (PID.TID 0000.0001) 3.678149882156126E+03, /* J =102 */ (PID.TID 0000.0001) 3.679977207983216E+03, /* J =103 */ (PID.TID 0000.0001) . . . (PID.TID 0000.0001) 3.762135540512856E+03, /* J =148 */ (PID.TID 0000.0001) 3.763959683900060E+03, /* J =149 */ (PID.TID 0000.0001) 3.765783757306327E+03, /* J =150 */ (PID.TID 0000.0001) 3.767607760697741E+03, /* J =151 */ (PID.TID 0000.0001) 3.769431694040391E+03, /* J =152 */ (PID.TID 0000.0001) 3.771255557300366E+03, /* J =153 */ (PID.TID 0000.0001) . . . (PID.TID 0000.0001) 3.853256318813865E+03, /* J =198 */ (PID.TID 0000.0001) 3.855076921635369E+03, /* J =199 */ (PID.TID 0000.0001) 3.856897452781851E+03 /* J =200 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) dyC = /* dyC(:,1,:,1) ( units: m ) */ (PID.TID 0000.0001) 8.685740105628031E+02 /* I = 1 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) dyC = /* dyC(1,:,1,:) ( units: m ) */ (PID.TID 0000.0001) 200 @ 8.685740105628031E+02 /* J = 1:200 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) dxV = /* dxV(:,1,:,1) ( units: m ) */ (PID.TID 0000.0001) 3.492326503864269E+03 /* I = 1 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) dxV = /* dxV(1,:,1,:) ( units: m ) */ (PID.TID 0000.0001) 3.492326503864269E+03, /* J = 1 */ (PID.TID 0000.0001) 3.494160597322059E+03, /* J = 2 */ (PID.TID 0000.0001) 3.495994625815115E+03, /* J = 3 */ (PID.TID 0000.0001) . . . (PID.TID 0000.0001) 3.578458116806316E+03, /* J = 48 */ (PID.TID 0000.0001) 3.580289120080414E+03, /* J = 49 */ (PID.TID 0000.0001) 3.582120056788447E+03, /* J = 50 */ (PID.TID 0000.0001) 3.583950926896370E+03, /* J = 51 */ (PID.TID 0000.0001) 3.585781730370146E+03, /* J = 52 */ (PID.TID 0000.0001) 3.587612467175734E+03, /* J = 53 */ (PID.TID 0000.0001) . . . (PID.TID 0000.0001) 3.669926070153822E+03, /* J = 98 */ (PID.TID 0000.0001) 3.671753703448232E+03, /* J = 99 */ (PID.TID 0000.0001) 3.673581268476031E+03, /* J =100 */ (PID.TID 0000.0001) 3.675408765203241E+03, /* J =101 */ (PID.TID 0000.0001) 3.677236193595885E+03, /* J =102 */ (PID.TID 0000.0001) 3.679063553619987E+03, /* J =103 */ (PID.TID 0000.0001) . . . (PID.TID 0000.0001) 3.761223442587002E+03, /* J =148 */ (PID.TID 0000.0001) 3.763047620951957E+03, /* J =149 */ (PID.TID 0000.0001) 3.764871729352929E+03, /* J =150 */ (PID.TID 0000.0001) 3.766695767756008E+03, /* J =151 */ (PID.TID 0000.0001) 3.768519736127280E+03, /* J =152 */ (PID.TID 0000.0001) 3.770343634432832E+03, /* J =153 */ (PID.TID 0000.0001) . . . (PID.TID 0000.0001) 3.852345990535555E+03, /* J =198 */ (PID.TID 0000.0001) 3.854166629181878E+03, /* J =199 */ (PID.TID 0000.0001) 3.855987196170102E+03 /* J =200 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) dyU = /* dyU(:,1,:,1) ( units: m ) */ (PID.TID 0000.0001) 8.685740105628031E+02 /* I = 1 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) dyU = /* dyU(1,:,1,:) ( units: m ) */ (PID.TID 0000.0001) 200 @ 8.685740105628031E+02 /* J = 1:200 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) rA = /* rA (:,1,:,1) ( units: m^2 ) */ (PID.TID 0000.0001) 3.034140565311787E+06 /* I = 1 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) rA = /* rA (1,:,1,:) ( units: m^2 ) */ (PID.TID 0000.0001) 3.034140565311787E+06, /* J = 1 */ (PID.TID 0000.0001) 3.035733583016748E+06, /* J = 2 */ (PID.TID 0000.0001) 3.037326544268204E+06, /* J = 3 */ (PID.TID 0000.0001) . . . (PID.TID 0000.0001) 3.108950903892753E+06, /* J = 48 */ (PID.TID 0000.0001) 3.110541236842415E+06, /* J = 49 */ (PID.TID 0000.0001) 3.112131511962616E+06, /* J = 50 */ (PID.TID 0000.0001) 3.113721729214045E+06, /* J = 51 */ (PID.TID 0000.0001) 3.115311888577043E+06, /* J = 52 */ (PID.TID 0000.0001) 3.116901990031955E+06, /* J = 53 */ (PID.TID 0000.0001) . . . (PID.TID 0000.0001) 3.188396127550019E+06, /* J = 98 */ (PID.TID 0000.0001) 3.189983532691603E+06, /* J = 99 */ (PID.TID 0000.0001) 3.191570878509831E+06, /* J =100 */ (PID.TID 0000.0001) 3.193158165004705E+06, /* J =101 */ (PID.TID 0000.0001) 3.194745392117253E+06, /* J =102 */ (PID.TID 0000.0001) 3.196332559837649E+06, /* J =103 */ (PID.TID 0000.0001) . . . (PID.TID 0000.0001) 3.267693152168335E+06, /* J =148 */ (PID.TID 0000.0001) 3.269277555701464E+06, /* J =149 */ (PID.TID 0000.0001) 3.270861898466484E+06, /* J =150 */ (PID.TID 0000.0001) 3.272446180404426E+06, /* J =151 */ (PID.TID 0000.0001) 3.274030401495632E+06, /* J =152 */ (PID.TID 0000.0001) 3.275614561720447E+06, /* J =153 */ (PID.TID 0000.0001) . . . (PID.TID 0000.0001) 3.346838291964839E+06, /* J =198 */ (PID.TID 0000.0001) 3.348419620256216E+06, /* J =199 */ (PID.TID 0000.0001) 3.350000886305247E+06 /* J =200 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) rAw = /* rAw(:,1,:,1) ( units: m^2 ) */ (PID.TID 0000.0001) 3.034140565311787E+06 /* I = 1 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) rAw = /* rAw(1,:,1,:) ( units: m^2 ) */ (PID.TID 0000.0001) 3.034140565311787E+06, /* J = 1 */ (PID.TID 0000.0001) 3.035733583016748E+06, /* J = 2 */ (PID.TID 0000.0001) 3.037326544268204E+06, /* J = 3 */ (PID.TID 0000.0001) . . . (PID.TID 0000.0001) 3.108950903892753E+06, /* J = 48 */ (PID.TID 0000.0001) 3.110541236842415E+06, /* J = 49 */ (PID.TID 0000.0001) 3.112131511962616E+06, /* J = 50 */ (PID.TID 0000.0001) 3.113721729214045E+06, /* J = 51 */ (PID.TID 0000.0001) 3.115311888577043E+06, /* J = 52 */ (PID.TID 0000.0001) 3.116901990031955E+06, /* J = 53 */ (PID.TID 0000.0001) . . . (PID.TID 0000.0001) 3.188396127550019E+06, /* J = 98 */ (PID.TID 0000.0001) 3.189983532691603E+06, /* J = 99 */ (PID.TID 0000.0001) 3.191570878509831E+06, /* J =100 */ (PID.TID 0000.0001) 3.193158165004705E+06, /* J =101 */ (PID.TID 0000.0001) 3.194745392117253E+06, /* J =102 */ (PID.TID 0000.0001) 3.196332559837649E+06, /* J =103 */ (PID.TID 0000.0001) . . . (PID.TID 0000.0001) 3.267693152168335E+06, /* J =148 */ (PID.TID 0000.0001) 3.269277555701464E+06, /* J =149 */ (PID.TID 0000.0001) 3.270861898466484E+06, /* J =150 */ (PID.TID 0000.0001) 3.272446180404426E+06, /* J =151 */ (PID.TID 0000.0001) 3.274030401495632E+06, /* J =152 */ (PID.TID 0000.0001) 3.275614561720447E+06, /* J =153 */ (PID.TID 0000.0001) . . . (PID.TID 0000.0001) 3.346838291964839E+06, /* J =198 */ (PID.TID 0000.0001) 3.348419620256216E+06, /* J =199 */ (PID.TID 0000.0001) 3.350000886305247E+06 /* J =200 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) rAs = /* rAs(:,1,:,1) ( units: m^2 ) */ (PID.TID 0000.0001) 3.033344035308899E+06 /* I = 1 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) rAs = /* rAs(1,:,1,:) ( units: m^2 ) */ (PID.TID 0000.0001) 3.033344035308899E+06, /* J = 1 */ (PID.TID 0000.0001) 3.034937081211127E+06, /* J = 2 */ (PID.TID 0000.0001) 3.036530070699164E+06, /* J = 3 */ (PID.TID 0000.0001) . . . (PID.TID 0000.0001) 3.108155715741703E+06, /* J = 48 */ (PID.TID 0000.0001) 3.109746077586438E+06, /* J = 49 */ (PID.TID 0000.0001) 3.111336381641027E+06, /* J = 50 */ (PID.TID 0000.0001) 3.112926627817013E+06, /* J = 51 */ (PID.TID 0000.0001) 3.114516816134055E+06, /* J = 52 */ (PID.TID 0000.0001) 3.116106946543010E+06, /* J = 53 */ (PID.TID 0000.0001) . . . (PID.TID 0000.0001) 3.187602402747711E+06, /* J = 98 */ (PID.TID 0000.0001) 3.189189837531316E+06, /* J = 99 */ (PID.TID 0000.0001) 3.190777213021051E+06, /* J =100 */ (PID.TID 0000.0001) 3.192364529177601E+06, /* J =101 */ (PID.TID 0000.0001) 3.193951785981312E+06, /* J =102 */ (PID.TID 0000.0001) 3.195538983412527E+06, /* J =103 */ (PID.TID 0000.0001) . . . (PID.TID 0000.0001) 3.266900927619873E+06, /* J =148 */ (PID.TID 0000.0001) 3.268485361541970E+06, /* J =149 */ (PID.TID 0000.0001) 3.270069734676302E+06, /* J =150 */ (PID.TID 0000.0001) 3.271654047042525E+06, /* J =151 */ (PID.TID 0000.0001) 3.273238298552185E+06, /* J =152 */ (PID.TID 0000.0001) 3.274822489224938E+06, /* J =153 */ (PID.TID 0000.0001) . . . (PID.TID 0000.0001) 3.346047604486870E+06, /* J =198 */ (PID.TID 0000.0001) 3.347628963894507E+06, /* J =199 */ (PID.TID 0000.0001) 3.349210261059796E+06 /* J =200 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) globalArea = /* Integrated horizontal Area (m^2) */ (PID.TID 0000.0001) 6.320689805195824E+08 (PID.TID 0000.0001) ; (PID.TID 0000.0001) // ======================================================= (PID.TID 0000.0001) // End of Model config. summary (PID.TID 0000.0001) // ======================================================= (PID.TID 0000.0001) (PID.TID 0000.0001) == Packages configuration : Check & print summary == (PID.TID 0000.0001) (PID.TID 0000.0001) OBCS_CHECK: #define ALLOW_OBCS (PID.TID 0000.0001) OBCS_CHECK: start summary: (PID.TID 0000.0001) useOBCSprescribe = /* prescribe OB values */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) useOBCSbalance = /* balance the flow through OB */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) OBCS_uvApplyFac = /* Factor to apply to U,V 2nd column/row */ (PID.TID 0000.0001) 1.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) OBCS_u1_adv_T = /* Temp uses upwind adv-scheme @ OB */ (PID.TID 0000.0001) 0 (PID.TID 0000.0001) ; (PID.TID 0000.0001) OBCS_u1_adv_S = /* Salt uses upwind adv-scheme @ OB */ (PID.TID 0000.0001) 0 (PID.TID 0000.0001) ; (PID.TID 0000.0001) OBCS_monitorFreq = /* monitor output frequency [s] */ (PID.TID 0000.0001) 2.592000000000000E+06 (PID.TID 0000.0001) ; (PID.TID 0000.0001) OBCS_monSelect = /* select group of variables to monitor */ (PID.TID 0000.0001) 0 (PID.TID 0000.0001) ; (PID.TID 0000.0001) useOBCStides = /* apply tidal forcing through OB */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) tidalPeriod = /* (s) */ (PID.TID 0000.0001) 10 @ 0.000000000000000E+00 /* I = 1: 10 */ (PID.TID 0000.0001) ; (PID.TID 0000.0001) OB_indexNone = /* null value for OB index (i.e. no OB) */ (PID.TID 0000.0001) -99 (PID.TID 0000.0001) ; (PID.TID 0000.0001) ======== Tile bi= 1 , bj= 1 ======== (PID.TID 0000.0001) OB_Jn = /* Northern OB local indices */ (PID.TID 0000.0001) 7 @ 200 /* I = -2: 4 */ (PID.TID 0000.0001) OB_Js = /* Southern OB local indices */ (PID.TID 0000.0001) 7 @ -99 /* I = -2: 4 */ (PID.TID 0000.0001) OB_Ie = /* Eastern OB local indices */ (PID.TID 0000.0001) 206 @ -99 /* J = -2:203 */ (PID.TID 0000.0001) OB_Iw = /* Western OB local indices */ (PID.TID 0000.0001) 206 @ -99 /* J = -2:203 */ (PID.TID 0000.0001) OBCS_CHECK: end summary. (PID.TID 0000.0001) OBCS_CHECK: set-up OK (PID.TID 0000.0001) OBCS_CHECK: check Inside Mask and OB locations: OK (PID.TID 0000.0001) SHELFICE_CHECK: #define ALLOW_SHELFICE (PID.TID 0000.0001) (PID.TID 0000.0001) SHELFICE_CHECK: start of SHELFICE config. summary (PID.TID 0000.0001) SHELFICEisOn = /* package is turned on */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) SHELFICEwriteState = /* do simple standard output */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) SHELFICE_dump_mdsio = /* use mdsio for snapshots */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) SHELFICE_tave_mdsio = /* use mdsio for time averages */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) SHELFICE_dump_mnc = /* use netcdf for snapshots */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) SHELFICE_tave_mnc = /* use netcdf for time averages */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) SHELFICE_dumpFreq = /* analoguous to dumpFreq */ (PID.TID 0000.0001) 2.592000000000000E+06 (PID.TID 0000.0001) ; (PID.TID 0000.0001) SHELFICE_taveFreq = /* analoguous to taveFreq */ (PID.TID 0000.0001) 0.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) useISOMIPTD = /* use simple isomip thermodynamics */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) SHELFICEconserve = /* use a conservative form of boundary conditions */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) SHELFICEboundaryLayer = /* use simple boundary layer scheme to suppress noise */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) SHELFICEadvDiffHeatFlux = /* use adv.-diff. instead of just diff. heat flux into the ice shelf */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) SHELFICEMassStepping = /* step forward ice shelf mass/thickness */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) no_slip_shelfice = /* use no slip boundary conditions */ (PID.TID 0000.0001) F (PID.TID 0000.0001) ; (PID.TID 0000.0001) SHELFICEdragLinear = /* linear drag coefficient */ (PID.TID 0000.0001) 0.000000000000000E+00 (PID.TID 0000.0001) ; (PID.TID 0000.0001) SHELFICEdragQuadratic = /* quadratic drag coefficient */ (PID.TID 0000.0001) 1.500000000000000E-03 (PID.TID 0000.0001) ; (PID.TID 0000.0001) SHELFICElatentHeat = /* latent heat of ice */ (PID.TID 0000.0001) 3.340000000000000E+05 (PID.TID 0000.0001) ; (PID.TID 0000.0001) SHELFICEheatCapacity_Cp = /* heat capacity of ice shelf */ (PID.TID 0000.0001) 2.000000000000000E+03 (PID.TID 0000.0001) ; (PID.TID 0000.0001) rhoShelfice = /* density of ice shelf */ (PID.TID 0000.0001) 9.170000000000000E+02 (PID.TID 0000.0001) ; (PID.TID 0000.0001) SHELFICEkappa = /* thermal conductivity of ice shelf */ (PID.TID 0000.0001) 1.540000000000000E-06 (PID.TID 0000.0001) ; (PID.TID 0000.0001) SHELFICEthetaSurface = /* surface temperature above i.s. */ (PID.TID 0000.0001) -2.000000000000000E+01 (PID.TID 0000.0001) ; (PID.TID 0000.0001) SHELFICEheatTransCoeff = /* heat transfer coefficient */ (PID.TID 0000.0001) 1.000000000000000E-04 (PID.TID 0000.0001) ; (PID.TID 0000.0001) SHELFICEsaltTransCoeff = /* salt transfer coefficient */ (PID.TID 0000.0001) 5.050000000000000E-07 (PID.TID 0000.0001) ; (PID.TID 0000.0001) SHELFICEuseGammaFrict = /* use velocity dependent exchange coefficients */ (PID.TID 0000.0001) T (PID.TID 0000.0001) ; (PID.TID 0000.0001) shiCdrag = /* quadr. drag coefficient for uStar */ (PID.TID 0000.0001) 1.500000000000000E-03 (PID.TID 0000.0001) ; (PID.TID 0000.0001) shiZetaN = /* parameter for gammaTurb */ (PID.TID 0000.0001) 5.200000000000000E-02 (PID.TID 0000.0001) ; (PID.TID 0000.0001) shiRc = /* parameter for gammaTurb (not used) */ (PID.TID 0000.0001) 2.000000000000000E-01 (PID.TID 0000.0001) ; (PID.TID 0000.0001) shiPrandtl = /* const. Prandtl No. for gammaTurb */ (PID.TID 0000.0001) 1.380000000000000E+01 (PID.TID 0000.0001) ; (PID.TID 0000.0001) shiSchmidt = /* const. Schmidt No. for gammaTurb */ (PID.TID 0000.0001) 2.432000000000000E+03 (PID.TID 0000.0001) ; (PID.TID 0000.0001) shiKinVisc = /* const. kin. viscosity for gammaTurb */ (PID.TID 0000.0001) 1.950000000000000E-06 (PID.TID 0000.0001) ; (PID.TID 0000.0001) SHELFICEloadAnomalyFile = /* file name of loaded loadAnomaly field */ (PID.TID 0000.0001) '' (PID.TID 0000.0001) ; (PID.TID 0000.0001) SHELFICEmassFile = /* file name of loaded mass field */ (PID.TID 0000.0001) 'shelficemassinit.bin' (PID.TID 0000.0001) ; (PID.TID 0000.0001) SHELFICEtopoFile = /* file name of loaded under-ice topography */ (PID.TID 0000.0001) 'shelftopo.round.bin' (PID.TID 0000.0001) ; (PID.TID 0000.0001) SHELFICEMassDynTendFile = /* file name of loaded dynamic mass tendency field */ (PID.TID 0000.0001) '' (PID.TID 0000.0001) ; (PID.TID 0000.0001) SHELFICE_CHECK: end of SHELFICE config. summary (PID.TID 0000.0001) GAD_CHECK: #define ALLOW_GENERIC_ADVDIFF (PID.TID 0000.0001) // ======================================================= (PID.TID 0000.0001) // Check Model config. (CONFIG_CHECK): (PID.TID 0000.0001) // CONFIG_CHECK : Normal End (PID.TID 0000.0001) // ======================================================= (PID.TID 0000.0001) (PID.TID 0000.0001) nRecords = 603 ; filePrec = 64 ; fileIter = 4320 (PID.TID 0000.0001) nDims = 2 , dims: (PID.TID 0000.0001) 1: 1 1 1 (PID.TID 0000.0001) 2: 200 1 200 (PID.TID 0000.0001) nFlds = 9 , nFl3D = 6 , fields: (PID.TID 0000.0001) >Uvel < >Vvel < >Theta < >Salt < >GuNm1 < >GvNm1 < >EtaN < >dEtaHdt < >EtaH < (PID.TID 0000.0001) missingVal= 1.00000000000000E+00 ; nTimRec = 1 , timeList: (PID.TID 0000.0001) 2.592000000000E+06 (PID.TID 0000.0001) READ_MFLDS_3D_RL: read field: "Uvel ", # 1 in fldList, rec= 1 (PID.TID 0000.0001) READ_MFLDS_3D_RL: read field: "Vvel ", # 2 in fldList, rec= 2 (PID.TID 0000.0001) READ_MFLDS_3D_RL: read field: "Theta ", # 3 in fldList, rec= 3 (PID.TID 0000.0001) READ_MFLDS_3D_RL: read field: "Salt ", # 4 in fldList, rec= 4 (PID.TID 0000.0001) READ_MFLDS_3D_RL: read field: "GuNm1 ", # 5 in fldList, rec= 5 (PID.TID 0000.0001) READ_MFLDS_3D_RL: read field: "GvNm1 ", # 6 in fldList, rec= 6 (PID.TID 0000.0001) READ_MFLDS_3D_RL: read field: "EtaN ", # 7 in fldList, rec= 601 (PID.TID 0000.0001) READ_MFLDS_3D_RL: read field: "dEtaHdt ", # 8 in fldList, rec= 602 (PID.TID 0000.0001) READ_MFLDS_3D_RL: read field: "EtaH ", # 9 in fldList, rec= 603 (PID.TID 0000.0001) READ_MFLDS_CHECK: - normal end ; reset MFLDS file-name: pickup.0000004320 (PID.TID 0000.0001) nRecords = 2 ; filePrec = 64 ; fileIter = 4320 (PID.TID 0000.0001) nDims = 2 , dims: (PID.TID 0000.0001) 1: 1 1 1 (PID.TID 0000.0001) 2: 200 1 200 (PID.TID 0000.0001) nFlds = 2 , nFl3D = 0 , fields: (PID.TID 0000.0001) >SHI_mass< >SHI_Rshe< (PID.TID 0000.0001) missingVal= 1.00000000000000E+00 ; nTimRec = 1 , timeList: (PID.TID 0000.0001) 2.592000000000E+06 (PID.TID 0000.0001) READ_MFLDS_3D_RL: read field: "SHI_mass", # 1 in fldList, rec= 1 (PID.TID 0000.0001) READ_MFLDS_3D_RL: read field: "SHI_Rshe", # 2 in fldList, rec= 2 (PID.TID 0000.0001) READ_MFLDS_CHECK: - normal end ; reset MFLDS file-name: pickup_shelfice.0000004320 (PID.TID 0000.0001) OBCS_FIELDS_LOAD: Reading initial data: 4320 2.592000000000E+06 (PID.TID 0000.0001) // ======================================================= (PID.TID 0000.0001) // Model current state (PID.TID 0000.0001) // ======================================================= (PID.TID 0000.0001) (PID.TID 0000.0001) // ======================================================= (PID.TID 0000.0001) // Begin MONITOR dynamic field statistics (PID.TID 0000.0001) // ======================================================= (PID.TID 0000.0001) %MON time_tsnumber = 4320 (PID.TID 0000.0001) %MON time_secondsf = 2.5920000000000E+06 (PID.TID 0000.0001) %MON dynstat_eta_max = 7.7686841200068E+00 (PID.TID 0000.0001) %MON dynstat_eta_min = -4.3604611272524E+00 (PID.TID 0000.0001) %MON dynstat_eta_mean = 1.2436574357276E+00 (PID.TID 0000.0001) %MON dynstat_eta_sd = 2.2651156948277E+00 (PID.TID 0000.0001) %MON dynstat_eta_del2 = 4.2564673798537E-01 (PID.TID 0000.0001) %MON dynstat_uvel_max = 0.0000000000000E+00 (PID.TID 0000.0001) %MON dynstat_uvel_min = 0.0000000000000E+00 (PID.TID 0000.0001) %MON dynstat_uvel_mean = 0.0000000000000E+00 (PID.TID 0000.0001) %MON dynstat_uvel_sd = 0.0000000000000E+00 (PID.TID 0000.0001) %MON dynstat_uvel_del2 = 0.0000000000000E+00 (PID.TID 0000.0001) %MON dynstat_vvel_max = 2.6420244052170E-01 (PID.TID 0000.0001) %MON dynstat_vvel_min = -6.1620832777777E-02 (PID.TID 0000.0001) %MON dynstat_vvel_mean = 8.3337793639787E-07 (PID.TID 0000.0001) %MON dynstat_vvel_sd = 5.0283823320597E-02 (PID.TID 0000.0001) %MON dynstat_vvel_del2 = 5.2526447789046E-05 (PID.TID 0000.0001) %MON dynstat_wvel_max = 1.2536446562343E-02 (PID.TID 0000.0001) %MON dynstat_wvel_min = -8.9564399579189E-03 (PID.TID 0000.0001) %MON dynstat_wvel_mean = 3.6243737454248E-05 (PID.TID 0000.0001) %MON dynstat_wvel_sd = 6.5696968313682E-04 (PID.TID 0000.0001) %MON dynstat_wvel_del2 = 8.1694392228506E-06 (PID.TID 0000.0001) %MON dynstat_theta_max = 1.9905000068298E+00 (PID.TID 0000.0001) %MON dynstat_theta_min = -1.7840768334392E+00 (PID.TID 0000.0001) %MON dynstat_theta_mean = 2.9683668376639E-01 (PID.TID 0000.0001) %MON dynstat_theta_sd = 1.2855478834066E+00 (PID.TID 0000.0001) %MON dynstat_theta_del2 = 1.7133634435050E-04 (PID.TID 0000.0001) %MON dynstat_salt_max = 3.4698782052158E+01 (PID.TID 0000.0001) %MON dynstat_salt_min = 3.4191827863278E+01 (PID.TID 0000.0001) %MON dynstat_salt_mean = 3.4457878208762E+01 (PID.TID 0000.0001) %MON dynstat_salt_sd = 1.8308362200513E-01 (PID.TID 0000.0001) %MON dynstat_salt_del2 = 1.8702511581632E-05 (PID.TID 0000.0001) %MON dynstat_sst_max = 0.0000000000000E+00 (PID.TID 0000.0001) %MON dynstat_sst_min = -1.1482385975654E+00 (PID.TID 0000.0001) %MON dynstat_sst_mean = -1.6313734931387E-01 (PID.TID 0000.0001) %MON dynstat_sst_sd = 1.7544506076465E-01 (PID.TID 0000.0001) %MON dynstat_sst_del2 = 2.4255296245715E-03 (PID.TID 0000.0001) %MON dynstat_sss_max = 3.4271933118386E+01 (PID.TID 0000.0001) %MON dynstat_sss_min = 0.0000000000000E+00 (PID.TID 0000.0001) %MON dynstat_sss_mean = 1.7555720399351E+01 (PID.TID 0000.0001) %MON dynstat_sss_sd = 1.7128820525889E+01 (PID.TID 0000.0001) %MON dynstat_sss_del2 = 2.4478723835272E-01 (PID.TID 0000.0001) %MON forcing_qnet_max = 0.0000000000000E+00 (PID.TID 0000.0001) %MON forcing_qnet_min = 0.0000000000000E+00 (PID.TID 0000.0001) %MON forcing_qnet_mean = 0.0000000000000E+00 (PID.TID 0000.0001) %MON forcing_qnet_sd = 0.0000000000000E+00 (PID.TID 0000.0001) %MON forcing_qnet_del2 = 0.0000000000000E+00 (PID.TID 0000.0001) %MON forcing_qsw_max = 0.0000000000000E+00 (PID.TID 0000.0001) %MON forcing_qsw_min = 0.0000000000000E+00 (PID.TID 0000.0001) %MON forcing_qsw_mean = 0.0000000000000E+00 (PID.TID 0000.0001) %MON forcing_qsw_sd = 0.0000000000000E+00 (PID.TID 0000.0001) %MON forcing_qsw_del2 = 0.0000000000000E+00 (PID.TID 0000.0001) %MON forcing_empmr_max = 0.0000000000000E+00 (PID.TID 0000.0001) %MON forcing_empmr_min = 0.0000000000000E+00 (PID.TID 0000.0001) %MON forcing_empmr_mean = 0.0000000000000E+00 (PID.TID 0000.0001) %MON forcing_empmr_sd = 0.0000000000000E+00 (PID.TID 0000.0001) %MON forcing_empmr_del2 = 0.0000000000000E+00 (PID.TID 0000.0001) %MON forcing_fu_max = 0.0000000000000E+00 (PID.TID 0000.0001) %MON forcing_fu_min = 0.0000000000000E+00 (PID.TID 0000.0001) %MON forcing_fu_mean = 0.0000000000000E+00 (PID.TID 0000.0001) %MON forcing_fu_sd = 0.0000000000000E+00 (PID.TID 0000.0001) %MON forcing_fu_del2 = 0.0000000000000E+00 (PID.TID 0000.0001) %MON forcing_fv_max = 0.0000000000000E+00 (PID.TID 0000.0001) %MON forcing_fv_min = 0.0000000000000E+00 (PID.TID 0000.0001) %MON forcing_fv_mean = 0.0000000000000E+00 (PID.TID 0000.0001) %MON forcing_fv_sd = 0.0000000000000E+00 (PID.TID 0000.0001) %MON forcing_fv_del2 = 0.0000000000000E+00 (PID.TID 0000.0001) %MON advcfl_uvel_max = 0.0000000000000E+00 (PID.TID 0000.0001) %MON advcfl_vvel_max = 1.8250772229565E-01 (PID.TID 0000.0001) %MON advcfl_wvel_max = 7.5218679374059E-01 (PID.TID 0000.0001) %MON advcfl_W_hf_max = 7.5218679374059E-01 (PID.TID 0000.0001) %MON pe_b_mean = 4.5983891786946E-02 (PID.TID 0000.0001) %MON ke_max = 3.4278554125270E-02 (PID.TID 0000.0001) %MON ke_mean = 1.2641436181447E-03 (PID.TID 0000.0001) %MON ke_vol = 4.5020187465590E+11 (PID.TID 0000.0001) %MON vort_r_min = 0.0000000000000E+00 (PID.TID 0000.0001) %MON vort_r_max = 0.0000000000000E+00 (PID.TID 0000.0001) %MON vort_a_mean = 0.0000000000000E+00 (PID.TID 0000.0001) %MON vort_a_sd = 0.0000000000000E+00 (PID.TID 0000.0001) %MON vort_p_mean = 0.0000000000000E+00 (PID.TID 0000.0001) %MON vort_p_sd = 0.0000000000000E+00 (PID.TID 0000.0001) %MON surfExpan_theta_mean = -7.3680754258453E-09 (PID.TID 0000.0001) %MON surfExpan_salt_mean = -3.9165444193929E-10 (PID.TID 0000.0001) // ======================================================= (PID.TID 0000.0001) // End MONITOR dynamic field statistics (PID.TID 0000.0001) // ======================================================= (PID.TID 0000.0001) // ======================================================= (PID.TID 0000.0001) // Begin OBCS MONITOR field statistics (PID.TID 0000.0001) // ======================================================= (PID.TID 0000.0001) %MON obc_N_vVel_max = 2.5000000000000E-02 (PID.TID 0000.0001) %MON obc_N_vVel_min = -2.5000000000000E-02 (PID.TID 0000.0001) %MON obc_N_vVel_mean = 9.4346236696664E-19 (PID.TID 0000.0001) %MON obc_N_vVel_sd = 1.4578823256425E-02 (PID.TID 0000.0001) %MON obc_N_vVel_Int = 3.6379788070917E-12 (PID.TID 0000.0001) // ======================================================= (PID.TID 0000.0001) // End OBCS MONITOR field statistics (PID.TID 0000.0001) // ======================================================= (PID.TID 0000.0001) SOLVE_FOR_PRESSURE: putPmEinXvector = F cg2d: Sum(rhs),rhsMax = -7.63447203059231E-03 6.44721831602382E+01 cg2d: Sum(rhs),rhsMax = -7.63637800688405E-03 6.44727549439110E+01 cg2d: Sum(rhs),rhsMax = -7.63828387711216E-03 6.44733268051595E+01 (PID.TID 0000.0001) INI_CG2D: CG2D normalisation factor = 2.2535974547295947E-04 (PID.TID 0000.0001) cg2d: Sum(rhs),rhsMax = 7.19363919848676E-03 7.01433028160164E+01 cg2d: Sum(rhs),rhsMax = 7.19277152121720E-03 7.01335453737095E+01 cg2d: Sum(rhs),rhsMax = 7.19171027088782E-03 7.01254120789553E+01 cg2d: Sum(rhs),rhsMax = 7.19048657037901E-03 7.01185759765009E+01 cg2d: Sum(rhs),rhsMax = 7.18919501996661E-03 7.01121398879100E+01 cg2d: Sum(rhs),rhsMax = 7.18782091221943E-03 7.01062633669734E+01 cg2d: Sum(rhs),rhsMax = 7.18638528780781E-03 7.01007562479761E+01 (PID.TID 0000.0001) %CHECKPOINT 4330 ckptA (PID.TID 0000.0001) Seconds in section "ALL [THE_MODEL_MAIN]": (PID.TID 0000.0001) User time: 3.139999866485596 (PID.TID 0000.0001) System time: 0.1400000005960464 (PID.TID 0000.0001) Wall clock time: 3.492056846618652 (PID.TID 0000.0001) No. starts: 1 (PID.TID 0000.0001) No. stops: 1 (PID.TID 0000.0001) Seconds in section "INITIALISE_FIXED [THE_MODEL_MAIN]": (PID.TID 0000.0001) User time: 3.9999999105930328E-002 (PID.TID 0000.0001) System time: 2.9999999329447746E-002 (PID.TID 0000.0001) Wall clock time: 0.1026549339294434 (PID.TID 0000.0001) No. starts: 1 (PID.TID 0000.0001) No. stops: 1 (PID.TID 0000.0001) Seconds in section "THE_MAIN_LOOP [THE_MODEL_MAIN]": (PID.TID 0000.0001) User time: 3.099999867379665 (PID.TID 0000.0001) System time: 0.1100000012665987 (PID.TID 0000.0001) Wall clock time: 3.389346122741699 (PID.TID 0000.0001) No. starts: 1 (PID.TID 0000.0001) No. stops: 1 (PID.TID 0000.0001) Seconds in section "INITIALISE_VARIA [THE_MAIN_LOOP]": (PID.TID 0000.0001) User time: 7.0000000298023224E-002 (PID.TID 0000.0001) System time: 1.9999997690320015E-002 (PID.TID 0000.0001) Wall clock time: 0.1125760078430176 (PID.TID 0000.0001) No. starts: 1 (PID.TID 0000.0001) No. stops: 1 (PID.TID 0000.0001) Seconds in section "MAIN LOOP [THE_MAIN_LOOP]": (PID.TID 0000.0001) User time: 3.029999867081642 (PID.TID 0000.0001) System time: 9.0000003576278687E-002 (PID.TID 0000.0001) Wall clock time: 3.276719093322754 (PID.TID 0000.0001) No. starts: 1 (PID.TID 0000.0001) No. stops: 1 (PID.TID 0000.0001) Seconds in section "MAIN_DO_LOOP [THE_MAIN_LOOP]": (PID.TID 0000.0001) User time: 3.029999867081642 (PID.TID 0000.0001) System time: 9.0000003576278687E-002 (PID.TID 0000.0001) Wall clock time: 3.276529550552368 (PID.TID 0000.0001) No. starts: 10 (PID.TID 0000.0001) No. stops: 10 (PID.TID 0000.0001) Seconds in section "FORWARD_STEP [MAIN_DO_LOOP]": (PID.TID 0000.0001) User time: 3.029999867081642 (PID.TID 0000.0001) System time: 9.0000003576278687E-002 (PID.TID 0000.0001) Wall clock time: 3.276172399520874 (PID.TID 0000.0001) No. starts: 10 (PID.TID 0000.0001) No. stops: 10 (PID.TID 0000.0001) Seconds in section "SHELFICE_REMESHING [FORWARD_STEP]": (PID.TID 0000.0001) User time: 1.9999980926513672E-002 (PID.TID 0000.0001) System time: 0.000000000000000 (PID.TID 0000.0001) Wall clock time: 3.2572746276855469E-002 (PID.TID 0000.0001) No. starts: 10 (PID.TID 0000.0001) No. stops: 10 (PID.TID 0000.0001) Seconds in section "DO_STATEVARS_DIAGS [FORWARD_STEP]": (PID.TID 0000.0001) User time: 0.000000000000000 (PID.TID 0000.0001) System time: 0.000000000000000 (PID.TID 0000.0001) Wall clock time: 2.6011466979980469E-002 (PID.TID 0000.0001) No. starts: 30 (PID.TID 0000.0001) No. stops: 30 (PID.TID 0000.0001) Seconds in section "LOAD_FIELDS_DRIVER [FORWARD_STEP]": (PID.TID 0000.0001) User time: 0.000000000000000 (PID.TID 0000.0001) System time: 0.000000000000000 (PID.TID 0000.0001) Wall clock time: 5.3286552429199219E-004 (PID.TID 0000.0001) No. starts: 10 (PID.TID 0000.0001) No. stops: 10 (PID.TID 0000.0001) Seconds in section "EXTERNAL_FLDS_LOAD [LOAD_FLDS_DRIVER]": (PID.TID 0000.0001) User time: 0.000000000000000 (PID.TID 0000.0001) System time: 0.000000000000000 (PID.TID 0000.0001) Wall clock time: 1.8525123596191406E-004 (PID.TID 0000.0001) No. starts: 10 (PID.TID 0000.0001) No. stops: 10 (PID.TID 0000.0001) Seconds in section "DO_ATMOSPHERIC_PHYS [FORWARD_STEP]": (PID.TID 0000.0001) User time: 0.000000000000000 (PID.TID 0000.0001) System time: 0.000000000000000 (PID.TID 0000.0001) Wall clock time: 1.7642974853515625E-004 (PID.TID 0000.0001) No. starts: 10 (PID.TID 0000.0001) No. stops: 10 (PID.TID 0000.0001) Seconds in section "DO_OCEANIC_PHYS [FORWARD_STEP]": (PID.TID 0000.0001) User time: 0.4899997860193253 (PID.TID 0000.0001) System time: 0.000000000000000 (PID.TID 0000.0001) Wall clock time: 0.4663519859313965 (PID.TID 0000.0001) No. starts: 10 (PID.TID 0000.0001) No. stops: 10 (PID.TID 0000.0001) Seconds in section "SHELFICE_THERMODYNAMICS [DO_OCEANIC_PHYS]": (PID.TID 0000.0001) User time: 1.9999980926513672E-002 (PID.TID 0000.0001) System time: 0.000000000000000 (PID.TID 0000.0001) Wall clock time: 2.2828578948974609E-003 (PID.TID 0000.0001) No. starts: 10 (PID.TID 0000.0001) No. stops: 10 (PID.TID 0000.0001) Seconds in section "DYNAMICS [FORWARD_STEP]": (PID.TID 0000.0001) User time: 0.8999997079372406 (PID.TID 0000.0001) System time: 1.0000001639127731E-002 (PID.TID 0000.0001) Wall clock time: 0.9058580398559570 (PID.TID 0000.0001) No. starts: 10 (PID.TID 0000.0001) No. stops: 10 (PID.TID 0000.0001) Seconds in section "UPDATE_SURF_DR [FORWARD_STEP]": (PID.TID 0000.0001) User time: 0.000000000000000 (PID.TID 0000.0001) System time: 0.000000000000000 (PID.TID 0000.0001) Wall clock time: 7.5650215148925781E-004 (PID.TID 0000.0001) No. starts: 10 (PID.TID 0000.0001) No. stops: 10 (PID.TID 0000.0001) Seconds in section "UPDATE_CG2D [FORWARD_STEP]": (PID.TID 0000.0001) User time: 1.0000050067901611E-002 (PID.TID 0000.0001) System time: 0.000000000000000 (PID.TID 0000.0001) Wall clock time: 8.1021785736083984E-003 (PID.TID 0000.0001) No. starts: 10 (PID.TID 0000.0001) No. stops: 10 (PID.TID 0000.0001) Seconds in section "SOLVE_FOR_PRESSURE [FORWARD_STEP]": (PID.TID 0000.0001) User time: 3.9999961853027344E-002 (PID.TID 0000.0001) System time: 0.000000000000000 (PID.TID 0000.0001) Wall clock time: 3.9734840393066406E-002 (PID.TID 0000.0001) No. starts: 10 (PID.TID 0000.0001) No. stops: 10 (PID.TID 0000.0001) Seconds in section "MOM_CORRECTION_STEP [FORWARD_STEP]": (PID.TID 0000.0001) User time: 3.0000209808349609E-002 (PID.TID 0000.0001) System time: 0.000000000000000 (PID.TID 0000.0001) Wall clock time: 1.6781091690063477E-002 (PID.TID 0000.0001) No. starts: 10 (PID.TID 0000.0001) No. stops: 10 (PID.TID 0000.0001) Seconds in section "INTEGR_CONTINUITY [FORWARD_STEP]": (PID.TID 0000.0001) User time: 1.9999980926513672E-002 (PID.TID 0000.0001) System time: 0.000000000000000 (PID.TID 0000.0001) Wall clock time: 2.9268026351928711E-002 (PID.TID 0000.0001) No. starts: 10 (PID.TID 0000.0001) No. stops: 10 (PID.TID 0000.0001) Seconds in section "CALC_SURF_DR [FORWARD_STEP]": (PID.TID 0000.0001) User time: 0.000000000000000 (PID.TID 0000.0001) System time: 0.000000000000000 (PID.TID 0000.0001) Wall clock time: 1.3232231140136719E-003 (PID.TID 0000.0001) No. starts: 10 (PID.TID 0000.0001) No. stops: 10 (PID.TID 0000.0001) Seconds in section "BLOCKING_EXCHANGES [FORWARD_STEP]": (PID.TID 0000.0001) User time: 6.9999933242797852E-002 (PID.TID 0000.0001) System time: 0.000000000000000 (PID.TID 0000.0001) Wall clock time: 7.5650215148925781E-002 (PID.TID 0000.0001) No. starts: 20 (PID.TID 0000.0001) No. stops: 20 (PID.TID 0000.0001) Seconds in section "THERMODYNAMICS [FORWARD_STEP]": (PID.TID 0000.0001) User time: 0.8000002205371857 (PID.TID 0000.0001) System time: 0.000000000000000 (PID.TID 0000.0001) Wall clock time: 0.8025257587432861 (PID.TID 0000.0001) No. starts: 10 (PID.TID 0000.0001) No. stops: 10 (PID.TID 0000.0001) Seconds in section "TRC_CORRECTION_STEP [FORWARD_STEP]": (PID.TID 0000.0001) User time: 0.3299998342990875 (PID.TID 0000.0001) System time: 0.000000000000000 (PID.TID 0000.0001) Wall clock time: 0.3202385902404785 (PID.TID 0000.0001) No. starts: 10 (PID.TID 0000.0001) No. stops: 10 (PID.TID 0000.0001) Seconds in section "MONITOR [FORWARD_STEP]": (PID.TID 0000.0001) User time: 0.000000000000000 (PID.TID 0000.0001) System time: 0.000000000000000 (PID.TID 0000.0001) Wall clock time: 1.7905235290527344E-004 (PID.TID 0000.0001) No. starts: 10 (PID.TID 0000.0001) No. stops: 10 (PID.TID 0000.0001) Seconds in section "DO_THE_MODEL_IO [FORWARD_STEP]": (PID.TID 0000.0001) User time: 0.3000002205371857 (PID.TID 0000.0001) System time: 6.9999996572732925E-002 (PID.TID 0000.0001) Wall clock time: 0.4851014614105225 (PID.TID 0000.0001) No. starts: 10 (PID.TID 0000.0001) No. stops: 10 (PID.TID 0000.0001) Seconds in section "DO_WRITE_PICKUP [FORWARD_STEP]": (PID.TID 0000.0001) User time: 1.9999980926513672E-002 (PID.TID 0000.0001) System time: 1.0000005364418030E-002 (PID.TID 0000.0001) Wall clock time: 6.1169147491455078E-002 (PID.TID 0000.0001) No. starts: 10 (PID.TID 0000.0001) No. stops: 10 (PID.TID 0000.0001) // ====================================================== (PID.TID 0000.0001) // Tile <-> Tile communication statistics (PID.TID 0000.0001) // ====================================================== (PID.TID 0000.0001) // o Tile number: 000001 (PID.TID 0000.0001) // No. X exchanges = 0 (PID.TID 0000.0001) // Max. X spins = 0 (PID.TID 0000.0001) // Min. X spins = 1000000000 (PID.TID 0000.0001) // Total. X spins = 0 (PID.TID 0000.0001) // Avg. X spins = 0.00E+00 (PID.TID 0000.0001) // No. Y exchanges = 0 (PID.TID 0000.0001) // Max. Y spins = 0 (PID.TID 0000.0001) // Min. Y spins = 1000000000 (PID.TID 0000.0001) // Total. Y spins = 0 (PID.TID 0000.0001) // Avg. Y spins = 0.00E+00 (PID.TID 0000.0001) // o Thread number: 000001 (PID.TID 0000.0001) // No. barriers = 8924 (PID.TID 0000.0001) // Max. barrier spins = 1 (PID.TID 0000.0001) // Min. barrier spins = 1 (PID.TID 0000.0001) // Total barrier spins = 8924 (PID.TID 0000.0001) // Avg. barrier spins = 1.00E+00 PROGRAM MAIN: Execution ended Normally