I got the error when I ran the model with WRF and ROMS option which is described in the below:
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forrtl: severe (174): SIGSEGV, segmentation fault occurred
Image PC Routine Line Source
coawstM 00000000038D5BFA Unknown Unknown Unknown
libpthread-2.17.s 00002B4AF22F95D0 Unknown Unknown Unknown
coawstM 00000000039C10E3 Unknown Unknown Unknown
coawstM 000000000393937C Unknown Unknown Unknown
coawstM 00000000004219BE cdecode_line_ 363 read_coawst_par.f90
coawstM 0000000000422897 read_model_inputs 59 read_model_inputs.f90
coawstM 000000000041A37D MAIN__ 68 master.f90
coawstM 0000000000417AE2 Unknown Unknown Unknown
libc-2.17.so 00002B4AF2A2E495 __libc_start_main Unknown UnknownCode: Select all
Cval(Nval)=TRIM(ADJUSTL(string))Code: Select all
status=cdecode_line(line, KeyWord, Nval, Cval, Rval)Code: Select all
! Number of parallel nodes assigned to each model in the coupled system.
! Their sum must be equal to the total number of processors.
NnodesATM = 70 ! atmospheric model
NnodesWAV = 0 ! wave model
NnodesOCN = 30 ! ocean model
NnodesHYD = 0 ! hydrology model
! Time interval (seconds) between coupling of models.
TI_ATM2WAV = 0.0d0 ! atmosphere to wave coupling interval
TI_ATM2OCN = 1800.0d0 ! atmosphere to ocean coupling interval
TI_WAV2ATM = 0.0d0 ! wave to atmosphere coupling interval
TI_WAV2OCN = 0.0d0 ! wave to ocean coupling interval
TI_OCN2WAV = 0.0d0 ! ocean to wave coupling interval
TI_OCN2ATM = 1800.0d0 ! ocean to atmosphere coupling interval
TI_OCN2HYD = 0.0d0 ! ocean to hydro coupling interval
TI_HYD2OCN = 0.0d0 ! hydro to ocean coupling interval
! Enter names of Atm, Wav, and Ocn input files.
! The Wav program needs multiple input files, one for each grid.
ATM_name = Projects/Doksuri/namelist.input ! atmospheric model
! WAV_name = Projects/Doksuri/swan.in
! Projects/Doksuri/swan_Doksuri_ref3.in ! wave model
! WAV_name = ww3_grid.inp
OCN_name = Projects/Doksuri/ocean.in ! ocean model
HYD_name = hydro.namelist ! hydro model
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TITLE = Hurricane Doksuri
! C-preprocessing Flag.
MyAppCPP = Doksuri
! Input variable information file name. This file needs to be processed
! first so all information arrays can be initialized properly.
VARNAME = ROMS/External/varinfo.dat
! Number of nested grids.
Ngrids = 1
! Number of grid nesting layers. This parameter is used to allow refinement
! and composite grid combinations.
NestLayers = 1
! Number of grids in each nesting layer [1:NestLayers].
GridsInLayer = 1 1
! Grid dimension parameters. See notes below in the Glossary for how to set
! these parameters correctly.
Lm == 475 ! Number of I-direction INTERIOR RHO-points -2
Mm == 301 ! Number of J-direction INTERIOR RHO-points -2
N == 16 ! Number of vertical levels
ND == 0 ! Number of wave directional bins
Nbed = 0 ! Number of sediment bed layers
NBAND = 30 ! Number of spectral irradiance bands
NAT = 2 ! Number of active tracers (usually, 2)
NPT = 0 ! Number of inactive passive tracers
NCS = 0 ! Number of cohesive (mud) sediment tracers
NNS = 0 ! Number of non-cohesive (sand) sediment tracers
! Domain decomposition parameters for serial, distributed-memory or
! shared-memory configurations used to determine tile horizontal range
! indices (Istr,Iend) and (Jstr,Jend), [1:Ngrids].
NtileI == 6 ! I-direction partition
NtileJ == 5 ! J-direction partition
! Set horizontal and vertical advection schemes for active and inert
! tracers. A different advection scheme is allowed for each tracer.
! For example, a positive-definite (monotonic) algorithm can be activated
! for salinity and inert tracers, while a different one is set for
! temperature. [1:NAT+NPT,Ngrids] values are expected.
!
! Keyword Advection Algorithm
!
! A4 4th-order Akima (horizontal/vertical)
! C2 2nd-order centered differences (horizontal/vertical)
! C4 4th-order centered differences (horizontal/vertical)
! HSIMT 3th-order HSIMT-TVD (horizontal/vertical)
! MPDATA recursive flux corrected MPDATA (horizontal/vertical)
! SPLINES parabolic splines (only vertical)
! SU3 split third-order upstream (horizontal/vertical)
! U3 3rd-order upstream-biased (only horizontal)
!
! The user has the option of specifying the full Keyword or the first
! two letters, regardless if using uppercase or lowercase. If nested
! grids, specify values for each grid (see glossary below).
Hadvection == U3 \
U3 \ ! temperature
U3 \
U3 ! salinity
Vadvection == C4 \
C4 \ ! temperature
C4 \
C4 ! salinity
! Adjoint-based algorithms can have different horizontal and schemes
! for active and inert tracers.
ad_Hadvection == U3 \ ! temperature
U3 ! salinity
ad_Vadvection == C4 \ ! temperature
C4 ! salinity
! Set lateral boundary conditions keyword. Notice that a value is expected
! for each boundary segment per nested grid for each state variable.
!
! Each tracer variable requires [1:4,1:NAT+NPT,Ngrids] values. Otherwise,
! [1:4,1:Ngrids] values are expected for other variables. The boundary
! order is: 1=west, 2=south, 3=east, and 4=north. That is, anticlockwise
! starting at the western boundary.
!
! The keyword is case insensitive and usually has three characters. However,
! it is possible to have compound keywords, if applicable. For example, the
! keyword "RadNud" implies radiation boundary condition with nudging. This
! combination is usually used in active/passive radiation conditions.
!
! Keyword Lateral Boundary Condition Type
!
! Cha Chapman_implicit (free-surface)
! Che Chapman_explicit (free-surface)
! Cla Clamped
! Clo Closed
! Fla Flather (2D momentum) _____N_____ j=Mm
! Gra Gradient | 4 |
! Nes Nested (refinement) | |
! Nud Nudging 1 W E 3
! Per Periodic | |
! Rad Radiation |_____S_____|
! Red Reduced Physics (2D momentum) 2 j=1
! Shc Shchepetkin (2D momentum) i=1 i=Lm
!
! W S E N
! e o a o
! s u s r
! t t t t
! h h
!
! 1 2 3 4
LBC(isFsur) == Clo Cha Cha Cha ! free-surface
LBC(isUbar) == Clo Fla Fla Fla ! 2D U-momentum
LBC(isVbar) == Clo Fla Fla Fla ! 2D V-momentum
LBC(isUvel) == Clo RadNud RadNud RadNud ! 3D U-momentum
LBC(isVvel) == Clo RadNud RadNud RadNud ! 3D V-momentum
LBC(isMtke) == Clo Gra Gra Gra ! mixing TKE
LBC(isTvar) == Clo RadNud RadNud RadNud \ ! temperature
Clo RadNud RadNud RadNud ! salinity
! Wec boundary conditions
LBC(isU2Sd) == Clo Gra Gra Gra ! 2D U-stokes
LBC(isV2Sd) == Clo Gra Gra Gra ! 2D V-stokes
LBC(isU3Sd) == Clo Gra Gra Gra ! 3D U-stokes
LBC(isV3Sd) == Clo Gra Gra Gra ! 3D V-stokes
! InWave boundary conditions
! LBC(isAC3d) == Gra Clo Gra Cla ! 3D wave action density
! LBC(isCT3d) == Gra Clo Gra Gra ! 3D wave theta celerity
! LBC(isCX3d) == Gra Clo Gra Gra ! 3D wave x-dir celerity
! LBC(isCY3d) == Gra Clo Gra Gra ! 3D wave y-dir celerity
! Ice boundary conditions
LBC(isAice) == Clo Clo Clo Clo ! ice concentration
LBC(isHice) == Clo Clo Clo Clo ! ice thickness
LBC(isHsno) == Clo Clo Clo Clo ! snow thickness
LBC(isTice) == Clo Clo Clo Clo ! ice temperature
! LBC(isApond)== Clo Clo Clo Clo ! surface water
LBC(isSfwat)== Clo Clo Clo Clo ! surface water
LBC(isSig11)== Clo Clo Clo Clo ! sigma-11
LBC(isSig12)== Clo Clo Clo Clo ! sigma-12
LBC(isSig22)== Clo Clo Clo Clo ! sigma-22
LBC(isUice) == Clo Clo Clo Clo ! ice U-momentum
LBC(isVice) == Clo Clo Clo Clo ! ice V-momentum
! Adjoint-based algorithms can have different lateral boundary
! conditions keywords.
ad_LBC(isFsur) == Cha Per Clo Per ! free-surface
ad_LBC(isUbar) == Fla Per Clo Per ! 2D U-momentum
ad_LBC(isVbar) == Fla Per Clo Per ! 2D U-momentum
ad_LBC(isUvel) == Gra Per Clo Per ! 3D U-momentum
ad_LBC(isVvel) == Gra Per Clo Per ! 3D V-momentum
ad_LBC(isMtke) == Gra Per Clo Per ! mixing TKE
ad_LBC(isTvar) == Gra Per Clo Per \ ! temperature
Gra Per Clo Per ! salinity
! Set lateral open boundary edge volume conservation switch for
! nonlinear model and adjoint-based algorithms. Usually activated
! with radiation boundary conditions to enforce global mass
! conservation, except if tidal forcing is enabled. [1:Ngrids].
VolCons(west) == F ! western boundary
VolCons(east) == F ! eastern boundary
VolCons(south) == F ! southern boundary
VolCons(north) == F ! northern boundary
ad_VolCons(west) == F ! western boundary
ad_VolCons(east) == F ! eastern boundary
ad_VolCons(south) == F ! southern boundary
ad_VolCons(north) == F ! northern boundary
! Time-Stepping parameters.
NTIMES == 86400 1
DT == 4.0d0 3.0d0
NDTFAST == 28 28
! Number of timesteps for computing observation impacts during the
! analysis-forecast cycle.
! NTIMES_ANA == 1800 ! analysis interval
! NTIMES_FCT == 1800 ! forecast interval
! Model iteration loops parameters.
ERstr = 1
ERend = 1
Nouter = 1
Ninner = 1
Nintervals = 1
! Number of eigenvalues (NEV) and eigenvectors (NCV) to compute for the
! Lanczos/Arnoldi problem in the Generalized Stability Theory (GST)
! analysis. NCV must be greater than NEV (see documentation below).
NEV = 2 ! Number of eigenvalues
NCV = 10 ! Number of eigenvectors
! Input/Output parameters.
NRREC == 0 0
LcycleRST == F T
NRST == 5400 120
NSTA == 1 1
NFLT == 1 1
NINFO == 1 1
! Output history, average, diagnostic files parameters.
LDEFOUT == T T
NHIS == 5400
NDEFHIS == 0
NQCK == 0
NDEFQCK == 0
NTSAVG == 1 1
NAVG == 5400
NDEFAVG == 0
NTSDIA == 1
NDIA == 5400
NDEFDIA == 0
! Output tangent linear and adjoint models parameters.
LcycleTLM == F
NTLM == 720
NDEFTLM == 0
LcycleADJ == F
NADJ == 720
NDEFADJ == 0
NSFF == 720
NOBC == 720
! GST output and check pointing restart parameters.
LmultiGST = F ! one eigenvector per file
LrstGST = F ! GST restart switch
MaxIterGST = 500 ! maximum number of iterations
NGST = 10 ! check pointing interval
! Relative accuracy of the Ritz values computed in the GST analysis.
Ritz_tol = 1.0d-15
! Harmonic/biharmonic horizontal diffusion of tracer for nonlinear model
! and adjoint-based algorithms: [1:NAT+NPT,Ngrids].
TNU2 == 0.2d0 0.2d0 0.2d0 0.2d0 ! m2/s
TNU4 == 0.0d0 0.0d0 ! m4/s
ad_TNU2 == 0.0d0 0.0d0 ! m2/s
ad_TNU4 == 0.0d0 0.0d0 ! m4/s
! Harmonic/biharmonic, horizontal viscosity coefficient for nonlinear model
! and adjoint-based algorithms: [Ngrids].
VISC2 == 0.10d0 0.10d0 ! m2/s
VISC4 == 0.0d0 ! m4/s
ad_VISC2 == 0.0d0 ! m2/s
ad_VISC4 == 0.0d0 ! m4/s
! Logical switches (TRUE/FALSE) to increase/decrease horizontal viscosity
! and/or diffusivity in specific areas of the application domain (like
! sponge areas) for the desired application grid.
LuvSponge == F ! horizontal momentum
LtracerSponge == F F ! temperature, salinity, inert
! Vertical mixing coefficients for tracers in nonlinear model and
! basic state scale factor in adjoint-based algorithms: [1:NAT+NPT,Ngrids]
AKT_BAK == 1.0d-6 1.0d-6 1.0d-6 1.0d-6 ! m2/s
ad_AKT_fac == 1.0d0 1.0d0 ! nondimensional
! Vertical mixing coefficient for momentum for nonlinear model and
! basic state scale factor in adjoint-based algorithms: [Ngrids].
AKV_BAK == 1.0d-5 ! m2/s
ad_AKV_fac == 1.0d0 ! nondimensional
! Upper threshold values to limit vertical mixing coefficients computed
! from vertical mixing parameterizations. Although this is an engineering
! fix, the vertical mixing values inferred from ocean observations are
! rarely higher than this upper limit value.
! AKT_LIMIT == 1.0d-3 1.0d-3 ! m2/s
! AKV_LIMIT == 1.0d-3 1.0d-3 ! m2/s
! Turbulent closure parameters.
AKK_BAK == 5.0d-6 ! m2/s
AKP_BAK == 5.0d-6 ! m2/s
TKENU2 == 0.0d0 ! m2/s
TKENU4 == 0.0d0 ! m4/s
! Generic length-scale turbulence closure parameters.
GLS_P == 3.0d0 ! K-epsilon
GLS_M == 1.5d0
GLS_N == -1.0d0
GLS_Kmin == 7.6d-6
GLS_Pmin == 1.0d-12
GLS_CMU0 == 0.5477d0
GLS_C1 == 1.44d0
GLS_C2 == 1.92d0
GLS_C3M == -0.4d0
GLS_C3P == 1.0d0
GLS_SIGK == 1.0d0
GLS_SIGP == 1.30d0
! Constants used in surface turbulent kinetic energy flux computation.
CHARNOK_ALPHA == 1400.0d0 ! Charnok surface roughness
ZOS_HSIG_ALPHA == 0.5d0 ! roughness from wave amplitude
SZ_ALPHA == 0.25d0 ! roughness from wave dissipation
CRGBAN_CW == 100.0d0 ! Craig and Banner wave breaking
WEC_ALPHA == 0.0d0 ! 0: all wave dissip goes to break and none to roller.
! 1: all wave dissip goes to roller and none to breaking.
! Constants used in momentum stress computation.
RDRG == 3.0d-04 ! m/s
RDRG2 == 0.025d0 ! nondimensional
Zob == 0.02d0 ! m
Zos == 0.02d0 ! m
! Height (m) of atmospheric measurements for Bulk fluxes parameterization.
BLK_ZQ == 2.0d0 ! air humidity
BLK_ZT == 2.0d0 ! air temperature
BLK_ZW == 10.0d0 ! winds
! Minimum depth for wetting and drying.
DCRIT == 0.10d0 ! m
! Various parameters.
WTYPE == 1
LEVSFRC == 15
LEVBFRC == 1
! Set vertical, terrain-following coordinates transformation equation and
! stretching function (see below for details), [1:Ngrids].
Vtransform == 2 ! transformation equation
Vstretching == 4 ! stretching function
! Vertical S-coordinates parameters (see below for details), [1:Ngrids].
THETA_S == 10.0d0 ! surface stretching parameter
THETA_B == 0.4d0 ! bottom stretching parameter
TCLINE == 50.0d0 ! critical depth (m)
! Mean Density and Brunt-Vaisala frequency.
RHO0 = 1025.0d0 ! kg/m3
BVF_BAK = 1.0d-5 ! 1/s2
! Time-stamp assigned for model initialization, reference time
! origin for tidal forcing, and model reference time for output
! NetCDF units attribute.
DSTART = 58009.0d0 ! days
TIDE_START = 58009.0d0 ! days
TIME_REF = 18581117.0d0 ! yyyymmdd.dd
! Nudging/relaxation time scales, inverse scales will be computed
! internally, [1:Ngrids].
TNUDG == 1.0d0 1.0d0 ! days
ZNUDG == 0.0d0 ! days
M2NUDG == 0.0d0 ! days
M3NUDG == 1.0d0 ! days
! Nudging/relaxation time scale for surface salinity nudging, inverse
! scales will be computed internally, [1:Ngrids].
TNUDG_SSS == 90.0d0 ! days
! Threshold to trigger SSS correction toward climatolgy,
! needs SCORRECTION and SSSC_THRESHOLD defined
SSS_MISMATCH_THRESHOLD = 0.2d0
! Factor between passive (outflow) and active (inflow) open boundary
! conditions, [1:Ngrids]. If OBCFAC > 1, nudging on inflow is stronger
! than on outflow (recommended).
OBCFAC == 0.0d0 ! nondimensional
! Linear equation of State parameters:
R0 == 1027.0d0 ! kg/m3
T0 == 10.0d0 ! Celsius
S0 == 30.0d0 ! nondimensional
TCOEF == 1.7d-4 ! 1/Celsius
SCOEF == 7.6d-4 ! nondimensional
! Slipperiness parameter: 1.0 (free slip) or -1.0 (no slip)
GAMMA2 == 1.0d0
! Logical switches (TRUE/FALSE) to activate horizontal momentum transport
! point Sources/Sinks (like river runoff transport) and mass point
! Sources/Sinks (like volume vertical influx), [1:Ngrids].
LuvSrc == F ! horizontal momentum transport
LwSrc == F ! volume vertical influx
! Logical switches (TRUE/FALSE) to activate tracers point Sources/Sinks
! (like river runoff) and to specify which tracer variables to consider:
! [1:NAT+NPT,Ngrids]. See glossary below for details.
LtracerSrc == F F ! temperature, salinity, inert
! Logical switches (TRUE/FALSE) to read and process climatology fields.
! See glossary below for details.
LsshCLM == F ! sea-surface height
Lm2CLM == F ! 2D momentum
Lm3CLM == F ! 3D momentum
LtracerCLM == F F ! temperature, salinity, inert
! Logical switches (TRUE/FALSE) to nudge the desired climatology field(s).
! If not analytical climatology fields, users need to turn ON the logical
! switches above to process the fields from the climatology NetCDF file
! that are needed for nudging. See glossary below for details.
/Sar
LnudgeM2CLM == F ! 2D momentum
LnudgeM3CLM == F ! 3D momentum
LnudgeTCLM == F F ! temperature, salinity, inert
! Logical switches for ice climatology and nudging
LmiCLM == F
LaiCLM == F
LsiCLM == F
LnudgeMICLM == F
LnudgeAICLM == F
LnudgeSICLM == F
! Starting (DstrS) and ending (DendS) day for adjoint sensitivity forcing.
! DstrS must be less or equal to DendS. If both values are zero, their
! values are reset internally to the full range of the adjoint integration.
DstrS == 0.0d0 ! starting day
DendS == 0.0d0 ! ending day
! Starting and ending vertical levels of the 3D adjoint state variables
! whose sensitivity is required.
KstrS == 1 ! starting level
KendS == 1 ! ending level
! Logical switches (TRUE/FALSE) to specify the adjoint state variables
! whose sensitivity is required.
Lstate(isFsur) == F ! free-surface
Lstate(isUbar) == F ! 2D U-momentum
Lstate(isVbar) == F ! 2D V-momentum
Lstate(isUvel) == F ! 3D U-momentum
Lstate(isVvel) == F ! 3D V-momentum
Lstate(isWvel) == F
Lstate(isTvar) == F F ! NT tracers
! Logical switches (TRUE/FALSE) to specify the state variables for
! which Forcing Singular Vectors or Stochastic Optimals is required.
Fstate(isFsur) == F ! free-surface
Fstate(isUbar) == F ! 2D U-momentum
Fstate(isVbar) == F ! 2D V-momentum
Fstate(isUvel) == F ! 3D U-momentum
Fstate(isVvel) == F ! 3D V-momentum
Fstate(isTvar) == F F ! NT tracers
Fstate(isUstr) == T ! surface U-stress
Fstate(isVstr) == T ! surface V-stress
Fstate(isTsur) == F F ! NT surface tracers flux
! Stochastic Optimals time decorrelation scale (days) assumed for
! red noise processes.
SO_decay == 2.0d0 ! days
! Stochastic Optimals surface forcing standard deviation for
! dimensionalization.
SO_sdev(isFsur) == 1.0d0 ! free-surface
SO_sdev(isUbar) == 1.0d0 ! 2D U-momentum
SO_sdev(isVbar) == 1.0d0 ! 2D V-momentum
SO_sdev(isUvel) == 1.0d0 ! 3D U-momentum
SO_sdev(isVvel) == 1.0d0 ! 3D V-momentum
SO_sdev(isTvar) == 1.0d0 1.0d0 ! NT tracers
SO_sdev(isUstr) == 1.0d0 ! surface U-stress
SO_sdev(isVstr) == 1.0d0 ! surface V-stress
SO_sdev(isTsur) == 1.0d0 1.0d0 ! NT surface tracers flux
! Logical switches (TRUE/FALSE) to activate writing of fields into
! HISTORY output file.
Hout(idUvel) == T ! u 3D U-velocity
Hout(idVvel) == T ! v 3D V-velocity
Hout(idu3dE) == F ! u_eastward 3D U-eastward at RHO-points
Hout(idv3dN) == F ! v_northward 3D V-northward at RHO-points
Hout(idWvel) == T ! w 3D W-velocity
Hout(idOvel) == T ! omega omega vertical velocity
Hout(idUbar) == T ! ubar 2D U-velocity
Hout(idVbar) == T ! vbar 2D V-velocity
Hout(idu2dE) == F ! ubar_eastward 2D U-eastward at RHO-points
Hout(idv2dN) == F ! vbar_northward 2D V-northward at RHO-points
Hout(idFsur) == T ! zeta free-surface
Hout(idBath) == T ! bath time-dependent bathymetry
Hout(idTvar) == T T ! temp, salt temperature and salinity
Hout(idUair) == F ! Uwind surface U-wind
Hout(idVair) == F ! Vwind surface V-wind
Hout(idUairE) == F ! Uwind_eastward surface U-wind
Hout(idVairN) == F ! Vwind_northward surface V-wind
Hout(idUsms) == T ! sustr surface U-stress
Hout(idVsms) == T ! svstr surface V-stress
Hout(idUbms) == T ! bustr bottom U-stress
Hout(idVbms) == T ! bvstr bottom V-stress
Hout(idUbrs) == T ! bustrc bottom U-current stress
Hout(idVbrs) == T ! bvstrc bottom V-current stress
Hout(idUbws) == T ! bustrw bottom U-wave stress
Hout(idVbws) == T ! bvstrw bottom V-wave stress
Hout(idUbcs) == T ! bustrcwmax bottom max wave-current U-stress
Hout(idVbcs) == T ! bvstrcwmax bottom max wave-current V-stress
Hout(idUVwc) == T ! bstrcwmax bottom max wave-current stress magnitude
Hout(idUbot) == T ! Ubot bed wave orbital U-velocity
Hout(idVbot) == T ! Vbot bed wave orbital V-velocity
Hout(idUbur) == T ! Ur bottom U-velocity above bed
Hout(idVbvr) == T ! Vr bottom V-velocity above bed
Hout(idW2xx) == F ! Sxx_bar WEC_Mellor 2D Sxx radiation stress
Hout(idW2xy) == F ! Sxy_bar WEC_Mellor 2D Sxy radiation stress
Hout(idW2yy) == F ! Syy_bar WEC_Mellor 2D Syy radiation stress
Hout(idW3xx) == F ! Sxx WEC_Mellor 3D Sxx radiation stress
Hout(idW3xy) == F ! Sxy WEC_Mellor 3D Sxy radiation stress
Hout(idW3yy) == F ! Syy WEC_Mellor 3D Syy radiation stress
Hout(idW3zx) == F ! Szx WEC_Mellor 3D Szx radiation stress
Hout(idW3zy) == F ! Szy WEC_Mellor 3D Szy radiation stress
Hout(idWztw) == T ! zetaw WEC_VF quasi-static sea level adjustment
Hout(idWqsp) == T ! qsp WEC_VF quasi-static pressure
Hout(idWbeh) == T ! bh WEC_VF Bernoulli head
Hout(idU2rs) == F ! ubar_Wecstress WEC 2D U-stress
Hout(idV2rs) == F ! vbar_Wecstress WEC 2D V-stress
Hout(idU3rs) == F ! u_Rstress WEC 3D U-stress
Hout(idV3rs) == F ! v_Rstress WEC 3D V-stress
Hout(idU2Sd) == T ! ubar_stokes 2D U-Stokes velocity
Hout(idV2Sd) == T ! vbar_stokes 2D V-Stokes velocity
Hout(idU3Sd) == T ! u_stokes 3D U-Stokes velocity
Hout(idV3Sd) == T ! v_stokes 3D V-Stokes velocity
Hout(idW3Sd) == T ! omega_stokes 3D Omega-Stokes velocity
Hout(idW3St) == T ! w_stokes 3D W-Stokes velocity
Hout(idWamp) == T ! Hwave wave height
Hout(idWlen) == T ! Lwave wave length-mean
Hout(idWlep) == T ! Lwavep wave length-peak
Hout(idWdir) == T ! Dwave wave direction
Hout(idWptp) == T ! Pwave_top wave surface period
Hout(idWpbt) == T ! Pwave_bot wave bottom period
Hout(idWorb) == T ! Uwave_rms wave bottom orbital velocity
Hout(idWbrk) == F ! Wave_break wave breaking (percent)
Hout(idUwav) == T ! uWave wave-depth avgeraged U-velocity
Hout(idVwav) == T ! vWave wave-depth avgeraged V-velocity
Hout(idWdif) == F ! Dissip_fric wave dissipation due to bottom friction
Hout(idWdib) == F ! Dissip_break wave dissipation due to breaking
Hout(idWdiw) == F ! Dissip_wcap wave dissipation due to white capping
Hout(idWdis) == F ! Dissip_roller wave roller dissipation
Hout(idWrol) == F ! rollA wave roller action density
Hout(idRunoff) == F ! Runoff surface runoff from land
Hout(idPair) == F ! Pair surface air pressure
Hout(idUair) == F ! Uair surface U-wind component
Hout(idVair) == F ! Vair surface V-wind component
Hout(idTsur) == F F ! shflux, ssflux surface net heat and salt flux
Hout(idLhea) == F ! latent latent heat flux
Hout(idShea) == F ! sensible sensible heat flux
Hout(idLrad) == F ! lwrad longwave radiation flux
Hout(idSrad) == F ! swrad shortwave radiation flux
Hout(idEmPf) == F ! EminusP E-P flux
Hout(idevap) == F ! evaporation evaporation rate
Hout(idrain) == F ! rain precipitation rate
Hout(idDano) == F ! rho density anomaly
Hout(idVvis) == T ! AKv vertical viscosity
Hout(idTdif) == F ! AKt vertical T-diffusion
Hout(idSdif) == F ! AKs vertical Salinity diffusion
Hout(idHsbl) == F ! Hsbl depth of surface boundary layer
Hout(idHbbl) == F ! Hbbl depth of bottom boundary layer
Hout(idMtke) == T ! tke turbulent kinetic energy
Hout(idMtls) == T ! gls turbulent length scale
! Logical switches (TRUE/FALSE) to activate writing of extra inert passive
! tracers other than biological and sediment tracers. An inert passive tracer
! is one that it is only advected and diffused. Other processes are ignored.
! These tracers include, for example, dyes, pollutants, oil spills, etc.
! NPT values are expected. However, these switches can be activated using
! compact parameter specification.
Hout(inert) == T ! dye_01, ... inert passive tracers
! Logical switches (TRUE/FALSE) to activate writing of exposed sediment
Qout(idUvel) == F ! u 3D U-velocity
Qout(idVvel) == F ! v 3D V-velocity
Qout(idu3dE) == F ! u_eastward 3D U-eastward at RHO-points
Qout(idv3dN) == F ! v_northward 3D V-northward at RHO-points
Qout(idWvel) == F ! w 3D W-velocity
Qout(idOvel) == F ! omega omega vertical velocity
Qout(idUbar) == T ! ubar 2D U-velocity
Qout(idVbar) == T ! vbar 2D V-velocity
Qout(idu2dE) == T ! ubar_eastward 2D U-eastward at RHO-points
Qout(idv2dN) == T ! vbar_northward 2D V-northward at RHO-points
Qout(idFsur) == T ! zeta free-surface
Qout(idBath) == T ! bath time-dependent bathymetry
Qout(idTvar) == F F ! temp, salt temperature and salinity
Qout(idUsur) == T ! u_sur surface U-velocity
Qout(idVsur) == T ! v_sur surface V-velocity
Qout(idUsuE) == T ! u_sur_eastward surface U-eastward velocity
Qout(idVsuN) == T ! v_sur_northward surface V-northward velocity
Qout(idsurT) == T T ! temp_sur, salt_sur surface temperature and salinity
Qout(idpthR) == F ! z_rho time-varying depths of RHO-points
Qout(idpthU) == F ! z_u time-varying depths of U-points
Qout(idpthV) == F ! z_v time-varying depths of V-points
Qout(idpthW) == F ! z_w time-varying depths of W-points
Qout(idUsms) == F ! sustr surface U-stress
Qout(idVsms) == F ! svstr surface V-stress
Qout(idUbms) == F ! bustr bottom U-stress
Qout(idVbms) == F ! bvstr bottom V-stress
Qout(idUbrs) == F ! bustrc bottom U-current stress
Qout(idVbrs) == F ! bvstrc bottom V-current stress
Qout(idUbws) == F ! bustrw bottom U-wave stress
Qout(idVbws) == F ! bvstrw bottom V-wave stress
Qout(idUbcs) == F ! bustrcwmax bottom max wave-current U-stress
Qout(idVbcs) == F ! bvstrcwmax bottom max wave-current V-stress
Qout(idUbot) == F ! Ubot bed wave orbital U-velocity
Qout(idVbot) == F ! Vbot bed wave orbital V-velocity
Qout(idUbur) == F ! Ur bottom U-velocity above bed
Qout(idVbvr) == F ! Vr bottom V-velocity above bed
Qout(idW2xx) == F ! Sxx_bar 2D radiation stress, Sxx component
Qout(idW2xy) == F ! Sxy_bar 2D radiation stress, Sxy component
Qout(idW2yy) == F ! Syy_bar 2D radiation stress, Syy component
Qout(idU2rs) == F ! Ubar_Rstress 2D radiation U-stress
Qout(idV2rs) == F ! Vbar_Rstress 2D radiation V-stress
Qout(idU2Sd) == F ! ubar_stokes 2D U-Stokes velocity
Qout(idV2Sd) == F ! vbar_stokes 2D V-Stokes velocity
Qout(idW3xx) == F ! Sxx 3D radiation stress, Sxx component
Qout(idW3xy) == F ! Sxy 3D radiation stress, Sxy component
Qout(idW3yy) == F ! Syy 3D radiation stress, Syy component
Qout(idW3zx) == F ! Szx 3D radiation stress, Szx component
Qout(idW3zy) == F ! Szy 3D radiation stress, Szy component
Qout(idU3rs) == F ! u_Rstress 3D U-radiation stress
Qout(idV3rs) == F ! v_Rstress 3D V-radiation stress
Qout(idU3Sd) == F ! u_stokes 3D U-Stokes velocity
Qout(idV3Sd) == F ! v_stokes 3D V-Stokes velocity
Qout(idWamp) == F ! Hwave wave height
Qout(idWlen) == F ! Lwave wave length
Qout(idWdir) == F ! Dwave wave direction-mean
Qout(idWdip) == F ! Dwavep wave direction-peak
Qout(idWptp) == F ! Pwave_top wave surface period
Qout(idWpbt) == F ! Pwave_bot wave bottom period
Qout(idWorb) == F ! Ub_swan wave bottom orbital velocity
Qout(idWdis) == F ! Wave_dissip wave dissipation
Qout(idPair) == F ! Pair surface air pressure
Qout(idTair) == F ! Tair surface air temperature
Qout(idUair) == F ! Uair surface U-wind component
Qout(idVair) == F ! Vair surface V-wind component
Qout(idTsur) == F F ! shflux, ssflux surface net heat and salt flux
Qout(idLhea) == F ! latent latent heat flux
Qout(idShea) == F ! sensible sensible heat flux
Qout(idLrad) == F ! lwrad longwave radiation flux
Qout(idSrad) == F ! swrad shortwave radiation flux
Qout(idEmPf) == F ! EminusP E-P flux
Qout(idevap) == F ! evaporation evaporation rate
Qout(idrain) == F ! rain precipitation rate
Qout(idDano) == F ! rho density anomaly
Qout(idVvis) == F ! AKv vertical viscosity
Qout(idTdif) == F ! AKt vertical T-diffusion
Qout(idSdif) == F ! AKs vertical Salinity diffusion
Qout(idHsbl) == F ! Hsbl depth of surface boundary layer
Qout(idHbbl) == F ! Hbbl depth of bottom boundary layer
Qout(idMtke) == F ! tke turbulent kinetic energy
Qout(idMtls) == F ! gls turbulent length scale
! Logical switches (TRUE/FALSE) to activate writing of extra inert passive
! tracers other than biological and sediment tracers into the QUICKSAVE
output file. An inert passive tracer is one that it is only advected and
! diffused. Other processes are ignored. These tracers include, for example,
! dyes, pollutants, oil spills, etc. NPT values are expected. However, these
! switches can be activated using compact parameter specification.
Qout(inert) == F ! dye_01, ... inert passive tracers
Qout(Snert) == F ! dye_01_sur, .. surface inert passive tracers
! layer properties into HISTORY output file. Currently, MBOTP properties
! are expected for the bottom boundary layer and/or sediment models:
!
! idBott( 1=isd50) grain_diameter mean grain diameter
! idBott( 2=idens) grain_density mean grain density
! idBott( 3=iwsed) settling_vel mean settling velocity
! idBott( 4=itauc) erosion_stress critical erosion stress
! idBott( 5=irlen) ripple_length ripple length
! idBott( 6=irhgt) ripple_height ripple height
! idBott( 7=ibwav) bed_wave_amp wave excursion amplitude
! idBott( 8=izdef) Zo_def default bottom roughness
! idBott( 9=izapp) Zo_app apparent bottom roughness
! idBott(10=izNik) Zo_Nik Nikuradse bottom roughness
! idBott(11=izbio) Zo_bio biological bottom roughness
! idBott(12=izbfm) Zo_bedform bed form bottom roughness
! idBott(13=izbld) Zo_bedload bed load bottom roughness
! idBott(14=izwbl) Zo_wbl wave bottom roughness
! idBott(15=iactv) active_layer_thickness active layer thickness
! idBott(16=ishgt) saltation saltation height
! idBott(17=imaxD) dep_net maximum inundation depth
! idBott(18=idnet) net erosion + dep Erosion or deposition
! idBott(19=idoff) tau critical offset dmix erodibility profile offset
! idBott(20=idslp) tau critical slope dmix or erodibility slope
! idBott(21=idtim) erodibility time scale erodibility profile restore time
! idBott(22=idbmx) diffusivity db_max Bed biodifusivity maximum
! idBott(23=idbmm) diffusivity db_m Bed biodifusivity minimum
! idBott(24=idbzs) diffusivity db_zs Bed biodifusivity zs
! idBott(25=idbzm) diffusivity db_zm Bed biodifusivity zm
! idBott(26=idbzp) diffusivity db_zphi Bed biodifusivity phi
! idBott(27=idprp) cohesive behavior cohesive behavior
!
! 1 1 1 1 1 1 1 1 1 1 2 2 2 2 2 2 2 2
! 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7
!
Hout(idBott) == T T T T T T T T T F F F F F T F T T F F F F F F F F F
! Logical switches (TRUE/FALSE) to activate writing of time-averaged
! fields into AVERAGE output file.
Aout(idUvel) == F ! u 3D U-velocity
Aout(idVvel) == F ! v 3D V-velocity
Aout(idu3dE) == F ! u_eastward 3D U-eastward at RHO-points
Aout(idv3dN) == F ! v_northward 3D V-northward at RHO-points
Aout(idWvel) == F ! w 3D W-velocity
Aout(idOvel) == F ! omega omega vertical velocity
Aout(idUbar) == F ! ubar 2D U-velocity
Aout(idVbar) == F ! vbar 2D V-velocity
Aout(idu2dE) == F ! ubar_eastward 2D U-eastward at RHO-points
Aout(idv2dN) == F ! vbar_northward 2D V-northward at RHO-points
Aout(idFsur) == F ! zeta free-surface
Aout(idBath) == F ! bath time-dependent bathymetry
Aout(idTvar) == F F ! temp, salt temperature and salinity
Aout(idUair) == F ! Uwind surface U-wind
Aout(idVair) == F ! Vwind surface V-wind
Aout(idUairE) == F ! Uwind_eastward surface U-wind
Aout(idVairN) == F ! Vwind_northward surface V-wind
Aout(idUsms) == F ! sustr surface U-stress
Aout(idVsms) == F ! svstr surface V-stress
Aout(idUbms) == F ! bustr bottom U-stress
Aout(idVbms) == F ! bvstr bottom V-stress
Aout(idUbrs) == F ! bustrc bottom U-current stress
Aout(idVbrs) == F ! bvstrc bottom V-current stress
Aout(idUbws) == F ! bustrw bottom U-wave stress
Aout(idVbws) == F ! bvstrw bottom V-wave stress
Aout(idUbcs) == F ! bustrcwmax bottom max wave-current U-stress
Aout(idVbcs) == F ! bvstrcwmax bottom max wave-current V-stress
Aout(idUVwc) == F ! bstrcwmax bottom max wave-current stress magnitude
Aout(idUbot) == F ! Ubot bed wave orbital U-velocity
Aout(idVbot) == F ! Vbot bed wave orbital V-velocity
Aout(idUbur) == F ! Ur bottom U-velocity above bed
Aout(idVbvr) == F ! Vr bottom V-velocity above bed
Aout(idW2xx) == F ! Sxx_bar WEC_Mellor 2D Sxx radiation stress
Aout(idW2xy) == F ! Sxy_bar WEC_Mellor 2D Sxy radiation stress
Aout(idW2yy) == F ! Syy_bar WEC_Mellor 2D Syy radiation stress
Aout(idW3xx) == F ! Sxx WEC_Mellor 3D Sxx radiation stress
Aout(idW3xy) == F ! Sxy WEC_Mellor 3D Sxy radiation stress
Aout(idW3yy) == F ! Syy WEC_Mellor 3D Syy radiation stress
Aout(idW3zx) == F ! Szx WEC_Mellor 3D Szx radiation stress
Aout(idW3zy) == F ! Szy WEC_Mellor 3D Szy radiation stress
Aout(idWztw) == F ! zetaw WEC_VF quasi-static sea level adjustment
Aout(idWqsp) == F ! qsp WEC_VF quasi-static pressure
Aout(idWbeh) == F ! bh WEC_VF Bernoulli head
Aout(idU2rs) == F ! ubar_Wecstress WEC 2D U-stress
Aout(idV2rs) == F ! vbar_Wecstress WEC 2D V-stress
Aout(idU3rs) == F ! u_Rstress WEC 3D U-stress
Aout(idV3rs) == F ! v_Rstress WEC 3D V-stress
Aout(idU2Sd) == F ! ubar_stokes 2D U-Stokes velocity
Aout(idV2Sd) == F ! vbar_stokes 2D V-Stokes velocity
Aout(idU3Sd) == F ! u_stokes 3D U-Stokes velocity
Aout(idV3Sd) == F ! v_stokes 3D V-Stokes velocity
Aout(idW3Sd) == F ! omega_stokes 3D Omega-Stokes velocity
Aout(idW3St) == F ! w_stokes 3D W-Stokes velocity
Aout(idWamp) == F ! Hwave wave height
Aout(idWlen) == F ! Lwave wave length-mean
Aout(idWlep) == F ! Lwavep wave length-peak
Aout(idWdir) == F ! Dwave wave direction
Aout(idWptp) == F ! Pwave_top wave surface period
Aout(idWpbt) == F ! Pwave_bot wave bottom period
Aout(idWorb) == F ! Uwave_rms wave bottom orbital velocity
Aout(idWbrk) == F ! Wave_break wave breaking (percent)
Aout(idUwav) == F ! uWave wave-depth avgeraged U-velocity
Aout(idVwav) == F ! vWave wave-depth avgeraged V-velocity
Aout(idWdif) == F ! Dissip_fric wave dissipation due to bottom friction
Aout(idWdib) == F ! Dissip_break wave dissipation due to breaking
Aout(idWdiw) == F ! Dissip_wcap wave dissipation due to white capping
Aout(idWdis) == F ! Dissip_roller wave roller dissipation
Aout(idWrol) == F ! rollA wave roller action density
Aout(idRunoff) == F ! Runoff surface runoff from land
Aout(idPair) == F ! Pair surface air pressure
Aout(idUair) == F ! Uair surface U-wind component
Aout(idVair) == F ! Vair surface V-wind component
Aout(idTsur) == F F ! shflux, ssflux surface net heat and salt flux
Aout(idLhea) == F ! latent latent heat flux
Aout(idShea) == F ! sensible sensible heat flux
Aout(idLrad) == F ! lwrad longwave radiation flux
Aout(idSrad) == F ! swrad shortwave radiation flux
Aout(idevap) == F ! evaporation evaporation rate
Aout(idrain) == F ! rain precipitation rate
Aout(idDano) == F ! rho density anomaly
Aout(idVvis) == F ! AKv vertical viscosity
Aout(idTdif) == F ! AKt vertical T-diffusion
Aout(idSdif) == T ! AKs vertical Salinity diffusion
Aout(idHsbl) == F ! Hsbl depth of surface boundary layer
Aout(idHbbl) == F ! Hbbl depth of bottom boundary layer
Aout(id2dRV) == F ! pvorticity_bar 2D relative vorticity
Aout(id3dRV) == F ! pvorticity 3D relative vorticity
Aout(id2dPV) == F ! rvorticity_bar 2D potential vorticity
Aout(id3dPV) == F ! rvorticity 3D potential vorticity
Aout(idu3dD) == F ! u_detided detided 3D U-velocity
Aout(idv3dD) == F ! v_detided detided 3D V-velocity
Aout(idu2dD) == F ! ubar_detided detided 2D U-velocity
Aout(idv2dD) == F ! vbar_detided detided 2D V-velocity
Aout(idFsuD) == F ! zeta_detided detided free-surface
Aout(idTrcD) == F F ! temp_detided, ... detided temperature and salinity
Aout(idHUav) == F ! Huon u-volume flux, Huon
Aout(idHVav) == F ! Hvom v-volume flux, Hvom
Aout(idUUav) == F ! uu quadratic <u*u> term
Aout(idUVav) == F ! uv quadratic <u*v> term
Aout(idVVav) == F ! vv quadratic <v*v> term
Aout(idU2av) == F ! ubar2 quadratic <ubar*ubar> term
Aout(idV2av) == F ! vbar2 quadratic <vbar*vbar> term
Aout(idZZav) == F ! zeta2 quadratic <zeta*zeta> term
Aout(idTTav) == F F ! temp_2, ... quadratic <t*t> tracer terms
Aout(idUTav) == F F ! u_temp, ... quadratic <u*t> tracer terms
Aout(idVTav) == F F ! v_temp, ... quadratic <v*t> tracer terms
Aout(iHUTav) == F F ! Huon_temp, ... tracer volume flux, <Huon*t>
Aout(iHVTav) == F F ! Hvom_temp, ... tracer volume flux, <Hvom*t>
! Logical switches (TRUE/FALSE) to activate writing of extra inert passive
! tracers other than biological and sediment tracers into the AVERAGE file.
Aout(inert) == F ! dye_01, ... inert passive tracers
! Logical switches (TRUE/FALSE) to activate writing of time-averaged,
! 2D momentum (ubar,vbar) diagnostic terms into DIAGNOSTIC output file.
Dout(M2rate) == F ! ubar_accel, ... acceleration
Dout(M2pgrd) == F ! ubar_prsgrd, ... pressure gradient
Dout(M2fcor) == F ! ubar_cor, ... Coriolis force
Dout(M2hadv) == F ! ubar_hadv, ... horizontal total advection
Dout(M2xadv) == F ! ubar_xadv, ... horizontal XI-advection
Dout(M2yadv) == F ! ubar_yadv, ... horizontal ETA-advection
Dout(M2hrad) == F ! ubar_hrad, ... horizontal total wec_mellor radiation stress
Dout(M2hvis) == F ! ubar_hvisc, ... horizontal total viscosity
Dout(M2xvis) == F ! ubar_xvisc, ... horizontal XI-viscosity
Dout(M2yvis) == F ! ubar_yvisc, ... horizontal ETA-viscosity
Dout(M2sstr) == F ! ubar_sstr, ... surface stress
Dout(M2bstr) == F ! ubar_bstr, ... bottom stress
Dout(M2fveg) == T
Dout(M2hjvf) == F ! 2D wec_vf horizontal J vortex force
Dout(M2kvrf) == F ! 2D wec_vf K vortex force
Dout(M2fsco) == F ! 2D wec_vf coriolis-stokes
Dout(M2bstm) == F ! 2D wec_vf bottom streaming
Dout(M2sstm) == F ! 2D wec_vf surface streaming
Dout(M2wrol) == F ! 2D wec_vf wave roller accel
Dout(M2wbrk) == F ! 2D wec_vf wave breaking
Dout(M2zeta) == F ! 2D wec_vf Eulerian sea level adjustment
Dout(M2zetw) == F ! 2D wec_vf quasi-static sea level adjustment
Dout(M2zqsp) == F ! 2D wec_vf quasi-static pressure
Dout(M2zbeh) == F ! 2D wec_vf Bernoulli head
! Logical switches (TRUE/FALSE) to activate writing of time-averaged,
! 3D momentum (u,v) diagnostic terms into DIAGNOSTIC output file.
Dout(M3rate) == F ! u_accel, ... acceleration
Dout(M3pgrd) == F ! u_prsgrd, ... pressure gradient
Dout(M3fcor) == F ! u_cor, ... Coriolis force
Dout(M3hadv) == F ! u_hadv, ... horizontal total advection
Dout(M3xadv) == F ! u_xadv, ... horizontal XI-advection
Dout(M3yadv) == F ! u_yadv, ... horizontal ETA-advection
Dout(M3vadv) == F ! u_vadv, ... vertical advection
Dout(M3hrad) == F ! u_hrad, ... horizontal total wec_mellor radiation stress
Dout(M3vrad) == F ! v_hrad, ... vertical total wec_mellor radiation stress
Dout(M3hvis) == F ! u_hvisc, ... horizontal total viscosity
Dout(M3xvis) == F ! u_xvisc, ... horizontal XI-viscosity
Dout(M3yvis) == F ! u_yvisc, ... horizontal ETA-viscosity
Dout(M3vvis) == F ! u_vvisc, ... vertical viscosity
Dout(M3fveg) == T ! u_fveg, ... vegetation drag force
Dout(M3vjvf) == F ! 3D wec_vf vertical J vortex force
Dout(M3hjvf) == F ! 3D wec_vf horizontal J vortex force
Dout(M3kvrf) == F ! 3D wec_vf K vortex force
Dout(M3fsco) == F ! 3D wec_vf coriolis-stokes
Dout(M3bstm) == F ! 3D wec_vf bottom streaming
Dout(M3sstm) == F ! 3D wec_vf surface streaming
Dout(M3wrol) == F ! 3D wec_vf wave roller accel
Dout(M3wbrk) == F ! 3D wec_vf wave breaking
! Logical switches (TRUE/FALSE) to activate writing of time-averaged,
! active (temperature and salinity) and passive (inert) tracer diagnostic
! terms into DIAGNOSTIC output file: [1:NAT+NPT,Ngrids].
Dout(iTrate) == F F ! temp_rate, ... time rate of change
Dout(iThadv) == F F ! temp_hadv, ... horizontal total advection
Dout(iTxadv) == F F ! temp_xadv, ... horizontal XI-advection
Dout(iTyadv) == F F ! temp_yadv, ... horizontal ETA-advection
Dout(iTvadv) == F F ! temp_vadv, ... vertical advection
Dout(iThdif) == F F ! temp_hdiff, ... horizontal total diffusion
Dout(iTxdif) == F F ! temp_xdiff, ... horizontal XI-diffusion
Dout(iTydif) == F F ! temp_ydiff, ... horizontal ETA-diffusion
Dout(iTsdif) == F F ! temp_sdiff, ... horizontal S-diffusion
Dout(iTvdif) == F F ! temp_vdiff, ... vertical diffusion
! Generic User parameters, [1:NUSER].
NUSER = 0
USER = 0.d0
! NetCDF-4/HDF5 compression parameters for output files.
NC_SHUFFLE = 1 ! if non-zero, turn on shuffle filter
NC_DEFLATE = 1 ! if non-zero, turn on deflate filter
NC_DLEVEL = 1 ! deflate level [0-9]
! Input NetCDF file names, [1:Ngrids].
GRDNAME == Projects/Doksuri/ROMS_COAWST_grd1.nc
ININAME == Projects/Doksuri/Doksuri_ini.nc
ITLNAME == ocean_itl.nc
IRPNAME == ocean_irp.nc
IADNAME == ocean_iad.nc
FWDNAME == ocean_fwd.nc
ADSNAME == ocean_ads.nc
IWININAME == inwave_ini.nc
IWSWNNAME == point1.spc2d
! Input adjoint forcing NetCDF filenames for computing observations
! impacts during the analysis-forecast cycle. If the forecast error
! metric is defined in state-space, then FOInameA and FOInameB should
! be regular adjoint forcing files just like ADSname. If the forecast
! error metric is defined in observation space (OBS_SPACE is activated)
! then the forecast is initialized OIFnameA and OIFnameB (specified in
! s4dvar.in input script) will have the structure of a 4D-Var observation
! file.
FOInameA == dogbone_foi_a.nc
FOInameB == dogbone_foi_b.nc
! Input NetCDF filenames for the forecasts initialized from the analysis
! of the current 4D-Var cycle (FCTnameA) and initialized from the analysis
! of the previous 4D-Var cycle (FCTnameB).
FCTnameA == dogbone_fct_a.nc
FCTnameB == dogbone_fct_b.nc
! Nesting grids connectivity data: contact points information. This
! NetCDF file is special and complex. It is currently generated using
! the script "matlab/grid/contact.m" from the Matlab repository.
NGCNAME = Projects/Doksuri/Doksuri_roms_contact.nc
! Input lateral boundary conditions and climatology file names. The
! USER has the option to split input data time records into several
! NetCDF files (see prologue instructions above). If so, use a single
! line per entry with a vertical bar (|) symbol after each entry,
! except the last one.
NCLMFILES == 1 ! number of climate files
CLMNAME == Projects/Doksuri/Doksuri_clm.nc
! CLMNAME == Projects/Sarika/coawst_clm_20161016.nc \
! Projects/Sarika/coawst_clm_20161017.nc
NBCFILES == 1 ! number of boundary files
BRYNAME == Projects/Doksuri/Doksuri_bdy.nc
! BRYNAME == Projects/Sarika4/coawst_bdy_20161016.nc \
! Projects/Sarika4/coawst_bdy_20161017.nc
! Input climatology nudging coefficients file name.
NUDNAME == ocean_nud.nc
! Input Sources/Sinks forcing (like river runoff) file name.
SSFNAME == ocean_rivers.nc
! Input tidal forcing file name.
TIDENAME == Projects/Doksuri/tide_forc_Doksuri.nc
! Input forcing NetCDF file name(s). The USER has the option to enter
! several file names for each nested grid. For example, the USER may
! have different files for wind products, heat fluxes, tides, etc.
! The model will scan the file list and will read the needed data from
! the first file in the list containing the forcing field. Therefore,
! the order of the file names is very important. If using multiple forcing
! files per grid, first enter all the file names for grid 1, then grid 2,
! and so on. It is also possible to split input data time records into
! several NetCDF files (see prologue instructions above). Use a single line
! per entry with a continuation (\) or vertical bar (|) symbol after each
! entry, except the last one.
! Input forcing NetCDF file name(s).
!
! The USER has the option to enter several sets of file names for each
! nested grid. For example, the USER may have different data for the
! wind products, heat fluxes, etc. Alternatively, if the all the forcing
! files are the same for nesting and the data is in its native resolution,
! we could enter only one set of files names and ROMS will replicate those
! files internally to the remaining grids using the plural KEYWORD protocol.
!
! The model will scan the files and will read the needed data from the first
! file in the list containing the forcing field. Therefore, the order of the
! filenames is critical. If using multiple forcing files per grid, first
! enter all the file names for grid one followed by two, and so on. It is
! also possible to split input data time records into several NetCDF files
! (see Prolog instructions above). Use a single line per entry with a
! continuation (\) or a vertical bar (|) symbol after each entry, except
! the last one.
NFFILES == 1
FRCNAME == Projects/Doksuri/tide_forc_Doksuri.nc
! Output NetCDF file names, [1:Ngrids].
GSTNAME == ocean_gst.nc
RSTNAME == ocean_rst.nc
HISNAME == ocean_hist.nc
TLMNAME == ocean_tlm.nc
TLFNAME == ocean_tlf.nc
ADJNAME == ocean_adj.nc
AVGNAME == ocean_avg.nc
DIANAME == ocean_dia.nc
STANAME == ocean_sta.nc
FLTNAME == ocean_flt.nc
! Input ASCII parameter filenames.
APARNAM = ROMS/External/s4dvar.in
SPOSNAM = ROMS/External/stations.in
FPOSNAM = ROMS/External/floats.in
BPARNAM = ROMS/External/bioFasham.in
SPARNAM = ROMS/External/sediment.in
USRNAME = ROMS/External/MyFile.datAny suggestions will be appreciated.