* Deltares, D-Flow FM Version **.**.**.7794M, Nov 14 2017, 16:09:23 * File creation date: 17:18:37, 28-11-2017 ** DEBUG : 0 0.1000020 NOD(KMAX) ** DEBUG : 6 0.7000140 XK (KMAX), YK (KMAX), ZK (KMAX), KC (KMAX), NMK (KMAX), RNOD(KMAX) ** DEBUG : 6 9.9999998E-03 XS(NSMAX) ** DEBUG : 6 9.9999998E-03 YS(NSMAX) ** DEBUG : 6 9.9999998E-03 ZS(NSMAX) ** DEBUG : 6 9.9999998E-03 IPSAM ** DEBUG : 7 5.0000001E-02 xlan(maxlan) ** DEBUG : 7 5.0000001E-02 ylan(maxlan) ** DEBUG : 7 5.0000001E-02 zlan(maxlan) ** DEBUG : 8 2.5000000E-02 nclan(maxlan) Until here copy of previous diagnostic file ** WARNING: TimeSplitInterval invalid, disabling time partitioning of output. Got: 0X ** WARNING: readMDUFile: [output] wrihis_density=1 was in file, but not used. Check possible typo. ** WARNING: readMDUFile: [output] wrihis_waterlevel_s1=1 was in file, but not used. Check possible typo. ** WARNING: readMDUFile: [output] wrihis_velocity_vector=1 was in file, but not used. Check possible typo. ** WARNING: readMDUFile: [output] wrihis_sediment=1 was in file, but not used. Check possible typo. ** WARNING: readMDUFile: [output] wrihis_constituents=1 was in file, but not used. Check possible typo. ** DEBUG : unc_read_net_ugrid: net file 'test_net.nc' is not UGRID. No problem, will fall back to old format reader. ** DEBUG : Opened 'test_net.nc' as # 3. ** DEBUG : Closed NetCDF file 'test_net.nc. ** INFO : Opened file : test_obs.xyn ** INFO : Closed file : test_obs.xyn ** INFO : Initializing flow model geometry... ** DEBUG : Opened 'test_net.nc' as # 3. ** WARNING: Could not read net cells from NetCDF file 'test_net.nc' (is not critical). Details follow: ** WARNING: NetCDF error: Variable not found (NetElemNode) ** WARNING: NetCDF error: Variable not found (NetElemLink) ** WARNING: NetCDF error: Invalid dimension id or name (nNetElemMaxNode) ** INFO : Opened file : test_sed1.ext ** INFO : Opened file : leftdis.pli ** INFO : Closed file : leftdis.pli ** INFO : boundary: 'leftdis.pli' opened 1 cells. ** INFO : dischargebnd leftdis.pli 1 nr of open bndcells ** DEBUG : addexternalboundarypoints: added 0 bnd points for SOBEK1D-FM2D connections. ** INFO : Done initializing flow model geometry. ** INFO : Opened file : test_sed1.mon ** INFO : Opened file : test_sed1.map ** INFO : Building kdtree... ** INFO : done ** INFO : Finding flow nodes... ** INFO : done in 0.00100 sec. ** INFO : Delete kdtree... ** INFO : Start initializing external forcings... ** INFO : External Forcing or Initialising 'dischargebnd' from file 'leftdis.pli'. ** INFO : External Forcing or Initialising 'initialtracerIM1' from file 'initracer.pol'. ** INFO : Opened file : initracer.pol ** INFO : Closed file : initracer.pol ** INFO : Opened file : DFM_interpreted_values_initracer.xyz ** INFO : Closed file : DFM_interpreted_values_initracer.xyz ** INFO : Closed file : test_sed1.ext ** INFO : No wind, so waves is switched off ** INFO : Done initializing external forcings. ** INFO : nogauss , nocg : 2 0 ** INFO : Building kdtree... ** INFO : done ** INFO : Finding flow nodes... ** INFO : done in 0.00000 sec. ** INFO : Delete kdtree... ** INFO : Modelinit finished at: 17:18:37, 28-11-2017 ** INFO : ** Model initialization was successful ** ** INFO : * Active Model definition: # Generated on 17:18:37, 28-11-2017 # Deltares, D-Flow FM Version **.**.**.7794M, Nov 14 2017, 16:09:23 [model] Program = D-Flow FM Version = **.**.**.7794M MDUFormatVersion = 1.05 # File format version (do not edit this) AutoStart = 2 # Autostart simulation after loading MDU (0: no, 1: autostart, 2: autostartstop) [geometry] NetFile = test_net.nc # Unstructured grid file *_net.nc BedlevelFile = # Bedlevels points file e.g. *.xyz, only needed for bedlevtype not equal 3 DryPointsFile = # Dry points file *.xyz (third column dummy z values), or dry areas polygon file *.pol (third column 1/-1: inside/outside) WaterLevIniFile = # Initial water levels sample file *.xyz LandBoundaryFile = # Land boundaries file *.ldb, used for visualization ThinDamFile = # Polyline file *_thd.pli, containing thin dams FixedWeirFile = # Polyline file *_fxw.pliz, containing fixed weirs with rows x, y, crest level, left ground level, right ground level Gulliesfile = # Polyline file *_gul.pliz, containing lowest bed level along talweg x, y, z level VertplizFile = # Vertical layering file *_vlay.pliz with rows x, y, Z, first Z, nr of layers, second Z, layer type ProflocFile = # Channel profile location file *_proflocation.xyz with rows x, y, z, profile number ref ProfdefFile = # Channel profile definition file *_profdefinition.def with definition for all profile numbers ProfdefxyzFile = # Channel profile definition file _profdefinition.def with definition for all profile numbers Uniformwidth1D = 2. # Uniform width for channel profiles not specified by profloc Uniformheight1D = 3. # Uniform height for channel profiles not specified by profloc StructureFile = # File *.ini containing list of structures (pumps, weirs, gates and general structures) ManholeFile = # File *.ini containing manholes PipeFile = # File *.pliz containing pipe-based 'culverts' ShipdefFile = # File *.shd containing ship definitions WaterLevIni = 0. # Initial water level at missing s0 values BedlevUni = -5. # Uniform bed level used at missing z values if BedlevType > 2 BedlevType = 3 # Bathymetry specification # 1: at cell centers (from BathymetryFile) # 2: at faces (from BathymetryFile) # 3: at nodes, face levels mean of node values # 4: at nodes, face levels min. of node values # 5: at nodes, face levels max. of node values # 6: at nodes, face levels max. of cell-center values Blmeanbelow = -999. # If not -999d0, below this level the cell center bed level is the mean of surrouding net nodes Blminabove = -999. # If not -999d0, above this level the cell center bed level is the min. of surrouding net nodes PartitionFile = # Domain partition polygon file *_part.pol for parallel run AngLat = 0. # Angle of latitude S-N (deg), 0: no Coriolis AngLon = 0. # Angle of longitude E-W (deg), 0: Greenwich, used in solar heat flux computation. Conveyance2D = 1 # -1: R=HU,0: R=H, 1: R=A/P, 2: K=analytic-1D conv, 3: K=analytic-2D conv Slotw2D = 0. # - Sillheightmin = 0.5 # Weir treatment only if both sills larger than this value (m) Makeorthocenters = 0 # Switch from circumcentres to orthocentres in geominit (i>=1: number of iterations, 0: do not use) Dcenterinside = 1. # Limit cell center (1.0: in cell, 0.0: on c/g) Bamin = 1.d-6 # Minimum grid cell area, in combination with cut cells OpenBoundaryTolerance = 3. # Search tolerance factor between boundary polyline and grid cells, in cell size units RenumberFlowNodes = 1 # Renumber the flow nodes (1: yes, 0: no) Kmx = 10 # Maximum number of vertical layers Layertype = 1 # Vertical layer type (1: all sigma, 2: all z, 3: use VertplizFile) Numtopsig = 0 # Number of sigma layers in top of z-layer model SigmaGrowthFactor = 1. # Layer thickness growth factor from bed up StretchType = -1 # Type of layer stretching, 0 = uniform, 1 = user defined, 2 = fixed level double exponential [numerics] CFLMax = 0.7 # Maximum Courant number Lincontin = 0 # Default 0; Set to 1 for linearizing d(Hu)/dx; link to AdvecType AdvecType = 33 # Advection type (0: none, 1: Wenneker, 2: Wenneker q(uio-u), 3: Perot q(uio-u), 4: Perot q(ui-u), 5: Perot q(ui-u) without itself) TimeStepType = 2 # Time step handling (0: only transport, 1: transport + velocity update, 2: full implicit step-reduce, 3: step-Jacobi, 4: explicit) Icoriolistype = 5 # 0=No, 1=yes, if jsferic then spatially varying, if icoriolistype==6 then constant (anglat) Limtyphu = 0 # Limiter type for waterdepth in continuity eqn. (0: none, 1: minmod, 2: van Leer, 3: Kooren, 4: monotone central) Limtypmom = 4 # Limiter type for cell center advection velocity (0: none, 1: minmod, 2: van Leer, 3: Kooren, 4: monotone central) Limtypsa = 4 # Limiter type for salinity transport (0: none, 1: minmod, 2: van Leer, 3: Kooren, 4: monotone central) TransportMethod = 1 # Transport method (0: Herman's method, 1: transport module) TransportTimestepping = 1 # Timestepping method in Transport module, 0 = global, 1 = local (default) Vertadvtypsal = 6 # Vertical advection type for salinity (0: none, 1: upwind explicit, 2: central explicit, 3: upwind implicit, 4: central implicit, 5: central implicit but upwind for neg. stratif., 6: higher order explicit, no Forester) Vertadvtyptem = 6 # Vertical advection type for temperature (0: none, 1: upwind explicit, 2: central explicit, 3: upwind implicit, 4: central implicit, 5: central implicit but upwind for neg. stratif., 6: higher order explicit, no Forester) Cffacver = 0. # Factor for including (1-CFL) in HO term vertical (0d0: no, 1d0: yes) Jarhoxu = 0 # Inlcude density gradient in advection term (0: no, 1: yes, 2: Also in barotrop and baroclin pressure term) Horadvtypzlayer = 0 # Horizontal advection treatment of z-layers (1: default, 2: sigma-like) Zlayeratubybob = 0 # Lowest connected cells governed by bob instead of by bL L/R Icgsolver = 4 # Solver type (1: sobekGS_OMP, 2: sobekGS_OMPthreadsafe, 3: sobekGS, 4: sobekGS + Saadilud, 5: parallel/global Saad, 6: parallel/Petsc, 7: parallel/GS) Maxdegree = 2 # Maximum degree in Gauss elimination Noderivedtypes = 5 # 0=use der. types. , 1 = less, 2 = lesser, 5 = also dealloc der. types FixedWeirScheme = 0 # Fixed weir scheme (0: none, 1: compact stencil, 2: whole tile lifted, full subgrid weir + factor) FixedWeirContraction = 1. # Fixed weir flow width contraction factor Fixedweirfrictscheme = 0 # Fixed weir friction scheme (0: friction based on hu, 1: friction based on subgrid weir friction scheme) Fixedweirtopwidth = 3. # Uniform width of the groyne part of fixed weirs Fixedweirtopfrictcoef = -999. # Uniform friction coefficient of the groyne part of fixed weirs Fixedweirtalud = 4. # Uniform talud slope of fixed weirs Izbndpos = 0 # Position of z boundary (0: D3Dflow, 1: on net boundary, 2: on specifiend polyline) Tlfsmo = 0. # Fourier smoothing time (s) on water level boundaries Logprofatubndin = 1 # ubnds inflow: 0=uniform U1, 1 = log U1, 2 = log U1 +(k-eps), 3=uniformk Slopedrop2D = 0. # Apply drop losses only if local bed slope > Slopedrop2D, (<=0: no drop losses) Drop3D = -999. # Apply droplosses in 3D if z upwind below bob + 2/3 hu*drop3D Chkadvd = 0.1 # Check advection terms if depth < chkadvdp, => less setbacks Trsh_u1Lb = 0. # 2D bedfriction in 3D below this threshold (m) Epshstem = 1.d-3 # Only compute heatflx + evap if depth > epshstem Zwsbtol = 0. # tolerance for zws(kb-1) at bed Keepzlayeringatbed = 1 # bedlayerthickness = zlayerthickness at bed 0 or 1 Teta0 = 0.55 # Theta of time integration (0.5 < theta < 1) Qhrelax = 1.d-2 # Relaxation on Q-h open boundaries Jbasqbnddownwindhs = 0 # Water depth scheme at discharge boundaries (0: original hu, 1: downwind hs) cstbnd = 0 # Delft-3D type velocity treatment near boundaries for small coastal models (1: yes, 0: no) Maxitverticalforestersal = 0 # Forester iterations for salinity (0: no vertical filter for salinity, > 0: max nr of iterations) Maxitverticalforestertem = 0 # Forester iterations for temperature (0: no vertical filter for temperature, > 0: max nr of iterations) Turbulencemodel = 3 # Turbulence model (0: none, 1: constant, 2: algebraic, 3: k-epsilon, 4: k-tau) Turbulenceadvection = 3 # Turbulence advection (0: none, 3: horizontally explicit and vertically implicit) Eddyviscositybedfacmax = 0. # Limit Eddyviscosity at bed ) AntiCreep = 0 # Include anti-creep calculation (0: no, 1: yes) Barocterm = 2 # (original = 1, current = 2 ) Maxwaterleveldiff = 0. # upper bound (in m) on water level changes (<= 0: no bounds). Run will abort when violated. Maxvelocitydiff = 0. # upper bound (in m/s) on velocity changes (<= 0: no bounds). Run will abort when violated. MinTimestepBreak = 0. # smallest allowed timestep (in s), checked on a sliding average of several timesteps. Run will abort when violated. Epshu = 1.d-4 # Threshold water depth for wet and dry cells SobekDFM_umin = 0. # Minimal velocity treshold for weir losses in Sobek-DFM coupling. SobekDFM_umin_method = 0 # Method for minimal velocity treshold for weir losses in Sobek-DFM coupling. SobekDFM_Minimal_1d2d_Embankment = 1.d-2 # Minimal crest height of 1D2D SOBEK-DFM embankments. sobekDFM_relax = 0.1 # Relaxation factor for SOBEK-DFM coupling algorithm. Vertadvtypmom = 3 # vertical advection for u1: 0: No, 3: Upwind implicit, 4: Central implicit, 5: QUICK implicit., 6: centerbased upwind expl jaupwindsrc = 1 # 1st-order upwind advection at sources/sinks (1) or higher-order (0) jasfer3D = 0 # corrections for spherical coordinates vicouv_filter = 0. # artificial viscosity for filtering (m2/s) [physics] UnifFrictCoef = 2.3d-2 # Uniform friction coefficient (0: no friction) UnifFrictType = 1 # Uniform friction type (0: Chezy, 1: Manning, 2: White-Colebrook, 3: idem, WAQUA style) UnifFrictCoef1D = 2.3d-2 # Uniform friction coefficient in 1D links (0: no friction) UnifFrictCoef1D2D = 2.3d-2 # Uniform friction coefficient in 1D links (0: no friction) UnifFrictCoefLin = 0. # Uniform linear friction coefficient for ocean models (m/s) (0: no friction) Umodlin = 1. # Linear friction umod, for ifrctyp=4,5,6 Vicouv = -1. # Uniform horizontal eddy viscosity (m2/s) Dicouv = -1. # Uniform horizontal eddy diffusivity (m2/s) Vicoww = 0. # Uniform vertical eddy viscosity (m2/s) Dicoww = 0. # Uniform vertical eddy diffusivity (m2/s) Vicwminb = 0. # Minimum visc in prod and buoyancy term (m2/s) Xlozmidov = 0. # Ozmidov length scale (m), default=0.0, no contribution of internal waves to vertical diffusion Smagorinsky = 0. # Smagorinsky factor in horizontal turbulence, e.g. 0.15 Elder = 0. # Elder factor in horizontal turbulence irov = 0 # 0=free slip, 1 = partial slip using wall_ks wall_ks = 0. # Wall roughness type (0: free slip, 1: partial slip using wall_ks) Rhomean = 1000. # Average water density (kg/m3) Idensform = 0 # Density calulation (0: uniform, 1: Eckard, 2: Unesco, 3: baroclinic case) Ag = 9.81 # Gravitational acceleration TidalForcing = 0 # Tidal forcing, if jsferic=1 (0: no, 1: yes) SelfAttractionLoading = 0 # Self attraction and loading (0=no, 1=yes, 2=only self attraction) Doodsonstart = 55.565 # TRIWAQ: 55.565, D3D: 57.555 Doodsonstop = 375.575 # TRIWAQ: 375.575, D3D: 275.555 Doodsoneps = 3.d-2 # TRIWAQ = 0.0 400 cmps , D3D = 0.03 60 cmps VillemonteCD1 = 1. # Calibration coefficient for Villemonte. Default = 1.0. NB. For Bloemberg data set 0.8 is recommended. VillemonteCD2 = 10. # Calibration coefficient for Villemonte. Default = 10.0. NB. For Bloemberg data set 0.8 is recommended. Salinity = 0 # Include salinity, (0=no, 1=yes) InitialSalinity = 1. # Uniform initial salinity concentration (ppt) Sal0abovezlev = -999. # Vertical level (m) above which salinity is set 0 DeltaSalinity = -999. # for testcases Salimax = -999. # Limit the salinity Salimin = 0. # Limit the salinity Backgroundsalinity = 30. # Background salinity for eqn. of state (ppt) Backgroundwatertemperature = 6. # Background water temperature for eqn. of state (deg C) Temperature = 0 # Include temperature (0: no, 1: only transport, 3: excess model of D3D, 5: composite (ocean) model) InitialTemperature = 6. # Uniform initial water temperature (degC) Secchidepth = 1. # Water clarity parameter (m) Stanton = -1. # Coefficient for convective heat flux, if negative, Ccon = abs(Stanton)*Cdwind Dalton = -1. # Coefficient for evaporative heat flux, if negative, Ceva = abs(Dalton)*Cdwind Tempmax = -999. # Limit the temperature Tempmin = 0. # Limit the temperature Surftempsmofac = 0. # Hor . Smoothing factor for surface water in heatflx comp. (0.0-1.0), 0=no SecondaryFlow = 0 # Secondary flow (0: no, 1: yes) EffectSpiral = 0. # Weight factor of the spiral flow intensity on transport angle BetaSpiral = 0. # Weight factor of the spiral flow intensity on flow dispersion stresses [sediment] Sedimentmodelnr = 0 # Sediment model nr, (0=no, 1=Krone, 2=SvR2007) SedFile = # Sediment characteristics file (*.sed) MorFile = # Morphology settings file (*.mor) Nr_of_sedfractions = 0 # Nr of sediment fractions, (specify the next parameters for each fraction) MxgrKrone = 0 # Highest fraction index treated by Krone Seddenscoupling = 0 # Sed rho coupling (0=no, 1 =yes [veg] Vegetationmodelnr = 0 # Vegetation model nr, (0=no, 1=Baptist DFM) Clveg = 0.8 # Stem distance factor, default 0.8 () Cdveg = 0.7 # Stem Cd coefficient , default 0.7 () Cbveg = 0. # Stem stiffness coefficient , default 0.7 () Rhoveg = 0. # Stem Rho, if > 0, -> bouyant stick procedure, default 0.0 () Stemheightstd = 0. # Stem height standard deviation fraction, e.g. 0.1 () [wind] ICdtyp = 2 # Wind drag coefficient type (1=Const; 2=Smith&Banke (2 pts); 3=S&B (3 pts); 4=Charnock 1955, 5=Whang 2005, 6=Wuest 2005, 7=Hersbach 2010 (2 pts) Cdbreakpoints = 6.3d-4 7.23d-3 # Wind drag coefficient break points Windspeedbreakpoints = 0. 100. # Wind speed break points (m/s) Relativewind = 0 # Wind speed relative to top-layer water speed, 1=yes, 0 = no) Rhoair = 1.2 # Air density (kg/m3) PavBnd = 0. # Average air pressure on open boundaries (N/m2) (only applied if > 0) Pavini = 0. # Average air pressure for initial water level correction (N/m2) (only applied if > 0) [grw] Infiltrationmodel = 0 # 0=No grw, 1=infiltration=interceptionlayer, 2=infiltration=Infiltrationvelocity, 3=model unsaturated/saturated ( ) Hinterceptionlayer = 0. # Intercept this amount of rain (m) Infiltrationvelocity = 0. # Infiltrationvelocity (m/s) Conductivity = 0. # non dimensionless K conductivity saturated (m/s), Q = K*A*i (m3/s) h_aquiferuni = 20. # bgrw = bl - h_aquiferuni (m), if negative, bgrw = bgrwuni h_unsatini = 0.200000002980232 # initial level groundwater is bedlevel - h_unsatini (m), if negative, sgrw = sgrwini [waves] Wavemodelnr = 0 # Wave model nr. (0: none, 1: fetch/depth limited hurdlestive, 2: Young-Verhagen, 3: SWAN, 4: wave group forcing, 5: uniform Wavenikuradse = 1.d-2 # Wave friction Nikuradse ks coefficient (m), used in Krone-Swart Rouwav = FR84 # Friction model for wave induced shear stress: FR84 (default) or: MS90, HT91, GM79, DS88, BK67, CJ85, OY88, VR04 Gammax = 1. # Maximum wave height/water depth ratio [time] RefDate = 20010101 # Reference date (yyyymmdd) Tzone = 0. # Time zone assigned to input time series DtUser = 3600. # Time interval (s) for external forcing update DtNodal = 21600. # Time interval (s) for updating nodal factors in astronomical boundary conditions DtMax = 120. # Maximal computation timestep (s) Dtfacmax = 1.1 # Max timestep increase factor ( ) DtInit = 30. # Initial computation timestep (s) Timestepanalysis = 0 # 0=no, 1=see file *.steps Tunit = S # Time unit for start/stop times (D, H, M or S) TStart = 0. # Start time w.r.t. RefDate (in TUnit) TStop = 864000. # Stop time w.r.t. RefDate (in TUnit) [restart] RestartFile = # Restart netcdf-file, either *_rst.nc or *_map.nc RestartDateTime = yyyymmdd_HHMMSS # Restart date and time (YYYYMMDDHHMMSS) when restarting from *_map.nc [external forcing] ExtForceFile = test_sed1.ext # Old format for external forcings file *.ext, link with tim/cmp-format boundary conditions specification ExtForceFileNew = # New format for external forcings file *.ext, link with bc-format boundary conditions specification Rainfall = 0 # Include rainfall, (0=no, 1=yes) [trachytopes] TrtRou = # Include alluvial and vegetation roughness (trachytopes) (Y: yes, N: no) TrtDef = # File (*.ttd) including trachytope definitions TrtL = # File (*.arl) including distribution of trachytope definitions DtTrt = 1200. # Trachytope roughness update time interval (s) [calibration] UseCalibration = 0 # Activate calibration factor friction multiplier (1 = yes, 0 = no) DefinitionFile = # File (*.cld) including calibration definitions AreaFile = # File (*.cll) including area distribution of calibration definitions [output] OutputDir = # Output directory of map-, his-, rst-, dat- and timings-files, default: DFM_OUTPUT_. Set to . for current dir. FlowGeomFile = # Flow geometry NetCDF *_flowgeom.nc ObsFile = test_obs.xyn # Points file *.xyn with observation stations with rows x, y, station name CrsFile = # Polyline file *_crs.pli defining observation cross sections FouFile = # Fourier analysis input file *.fou HisFile = # HisFile name *_his.nc MapFile = # MapFile name *_map.nc HisInterval = 3600. 0. 864000. # History output times, given as "interval" "start period" "end period" (s) XLSInterval = 0. # Interval (s) between XLS history MapInterval = 3600. 0. 864000. # Map file output, given as "interval" "start period" "end period" (s) RstInterval = 0. 0. 864000. # Restart file output times, given as "interval" "start period" "end period" (s) S1incinterval = 0. # Interval (m) in incremental file for water levels S1 WaqInterval = 3600. 0. 864000. # DELWAQ output times, given as "interval" "start period" "end period" (s) StatsInterval = -60. # Screen step output interval in seconds simulation time, if negative in seconds wall clock time WriteBalancefile = 0 # Write balance file (1: yes, 0: no) TimingsInterval = 0. # Timings statistics output interval TimeSplitInterval = 0X # Time splitting interval, after which a new output file is started. value+unit, e.g. '1 M', valid units: Y,M,D,h,m,s. MapFormat = 4 # Map file format, 1: netCDF, 2: Tecplot, 3: netCFD and Tecplot, 4: NetCDF-UGRID Wrihis_balance = 1 # Write mass balance totals to his file (1: yes, 0: no) Wrihis_sourcesink = 1 # Write sources-sinks statistics to his file (1=yes, 0=no) Wrihis_structure_gen = 1 # Write general structure parameters to his file (1: yes, 0: no) Wrihis_structure_dam = 1 # Write dam parameters to his file (1: yes, 0: no) Wrihis_structure_pump = 1 # Write pump parameters to his file (1: yes, 0: no) Wrihis_structure_gate = 1 # Write gate parameters to his file (1: yes, 0: no) Wrihis_structure_weir = 1 # Write weir parameters to his file (1: yes, 0: no) Wrihis_turbulence = 1 # Write k, eps and vicww to his file (1: yes, 0: no) Wrihis_wind = 1 # Write wind velocities to his file (1: yes, 0: no) Wrihis_rain = 1 # Write precipitation to his file (1: yes, 0: no) Wrihis_temperature = 1 # Write temperature to his file (1: yes, 0: no) Wrihis_heatflux = 0 # Write heat flux to his file (1: yes, 0: no) Wrihis_salinity = 1 # Write salinity to his file (1: yes, 0: no) Wrimap_waterlevel_s0 = 1 # Write water levels for previous time step to map file (1: yes, 0: no) Wrimap_waterlevel_s1 = 1 # Write water levels to map file (1: yes, 0: no) Wrimap_volume1 = 0 # Write volumes to map file (1: yes, 0: no) Wrimap_velocity_component_u0 = 1 # Write velocity component for previous time step to map file (1: yes, 0: no) Wrimap_velocity_component_u1 = 1 # Write velocity component to map file (1: yes, 0: no) Wrimap_velocity_vector = 1 # Write cell-center velocity vectors to map file (1: yes, 0: no) Wrimap_upward_velocity_component = 1 # Write upward velocity component on cell interfaces (1: yes, 0: no) Wrimap_density_rho = 1 # Write flow density to map file (1: yes, 0: no) Wrimap_horizontal_viscosity_viu = 1 # Write horizontal viscosity to map file (1: yes, 0: no) Wrimap_horizontal_diffusivity_diu = 1 # Write horizontal diffusivity to map file (1: yes, 0: no) Wrimap_flow_flux_q1 = 1 # Write flow flux to map file (1: yes, 0: no) Wrimap_spiral_flow = 1 # Write spiral flow to map file (1: yes, 0: no) Wrimap_numlimdt = 1 # Write the number times a cell was Courant limiting to map file (1: yes, 0: no) Wrimap_taucurrent = 1 # Write the shear stress to map file (1: yes, 0: no) Wrimap_chezy = 1 # Write the chezy roughness to map file (1: yes, 0: no) Wrimap_turbulence = 1 # Write vicww, k and eps to map file (1: yes, 0: no) Wrimap_constituents = 1 # Write constituents to map file (1: yes, 0: no) Wrimap_wind = 1 # Write wind velocities to map file (1: yes, 0: no) MapOutputTimeVector = # File (*.mpt) containing fixed map output times (s) w.r.t. RefDate FullGridOutput = 0 # Full grid output mode (0: compact, 1: full time-varying grid data) EulerVelocities = 0 # Euler velocities output (0: GLM, 1: Euler velocities) Wrirst_bnd = 1 # Write waterlevel, bedlevel and coordinates of boundaries to restart files Writepart_domain = 1 # Write partition domain info. for postprocessing [particles] ParticlesFile = AddTracer = 0 # add tracer (1) or not (other) StartTime = 0. # starttime (if >0) TimeStep = 0. # time step (>0) or every computational time step [processes] SubstanceFile = sed1fraction_5tau.sub # ProcesDatabaseFile = proc_def.dat # ** INFO : ** ** INFO : Start of the computation time loop ** INFO : Writing initial output to file(s)... ** DEBUG : Opened NetCDF file 'DFM_OUTPUT_test_sed1\test_sed1_his.nc' as #5. ** DEBUG : Opened NetCDF file 'DFM_OUTPUT_test_sed1\test_sed1_map.nc' as #6. ** INFO : In waq_wri_model_files(). ** INFO : Opened file : DFM_DELWAQ_test_sed1\test_sed1.hyd ** INFO : Closed file : DFM_DELWAQ_test_sed1\test_sed1.hyd ** DEBUG : Opened NetCDF file 'DFM_DELWAQ_test_sed1\test_sed1_waqgeom.nc' as #7. ** DEBUG : Closed NetCDF file 'DFM_DELWAQ_test_sed1\test_sed1_waqgeom.nc. ** INFO : Opened file : DFM_DELWAQ_test_sed1\test_sed1.bnd ** INFO : Closed file : DFM_DELWAQ_test_sed1\test_sed1.bnd ** INFO : Opened file : DFM_DELWAQ_test_sed1\test_sed1.poi ** INFO : Opened file : DFM_DELWAQ_test_sed1\test_sed1.len ** INFO : Opened file : DFM_DELWAQ_test_sed1\test_sed1.srf ** INFO : Opened file : DFM_DELWAQ_test_sed1\test_sed1.srfold ** INFO : Opened file : DFM_DELWAQ_test_sed1\test_sed1.atr ** INFO : In waq_wri_couple_files: # 0, time: 0.000000000000000E+000 ** INFO : Opened file : DFM_DELWAQ_test_sed1\test_sed1.vol ** INFO : Opened file : DFM_DELWAQ_test_sed1\test_sed1.tau ** INFO : Opened file : DFM_DELWAQ_test_sed1\test_sed1.vdf ** INFO : Done writing initial output to file(s). ** INFO : In waq_wri_couple_files: # 1, time: 3600.00000000000 ** INFO : Opened file : DFM_DELWAQ_test_sed1\test_sed1.are ** INFO : Opened file : DFM_DELWAQ_test_sed1\test_sed1.flo ** INFO : In waq_wri_couple_files: # 2, time: 7200.00000000000 ** INFO : Sim. time done Sim. time left Real time used Real time left Steps left Complete% Interval-averaged time step ** INFO : 0d 2:00:00 9d 22:00:00 0d 0:00:00 0d 0:00:05 238 0.8% 0.00000 ** INFO : In waq_wri_couple_files: # 3, time: 10800.0000000000 ** INFO : In waq_wri_couple_files: # 4, time: 14400.0000000000 ** INFO : In waq_wri_couple_files: # 5, time: 18000.0000000000 ** INFO : In waq_wri_couple_files: # 6, time: 21600.0000000000 ** INFO : In waq_wri_couple_files: # 7, time: 25200.0000000000 ** INFO : In waq_wri_couple_files: # 8, time: 28800.0000000000 ** INFO : In waq_wri_couple_files: # 9, time: 32400.0000000000 ** INFO : In waq_wri_couple_files: # 10, time: 36000.0000000000 ** INFO : In waq_wri_couple_files: # 11, time: 39600.0000000000 ** INFO : In waq_wri_couple_files: # 12, time: 43200.0000000000 ** INFO : In waq_wri_couple_files: # 13, time: 46800.0000000000 ** INFO : In waq_wri_couple_files: # 14, time: 50400.0000000000 ** INFO : In waq_wri_couple_files: # 15, time: 54000.0000000000 ** INFO : In waq_wri_couple_files: # 16, time: 57600.0000000000 ** INFO : In waq_wri_couple_files: # 17, time: 61200.0000000000 ** INFO : In waq_wri_couple_files: # 18, time: 64800.0000000000 ** INFO : In waq_wri_couple_files: # 19, time: 68400.0000000000 ** INFO : In waq_wri_couple_files: # 20, time: 72000.0000000000 ** INFO : In waq_wri_couple_files: # 21, time: 75600.0000000000 ** INFO : In waq_wri_couple_files: # 22, time: 79200.0000000000 ** INFO : In waq_wri_couple_files: # 23, time: 82800.0000000000 ** INFO : In waq_wri_couple_files: # 24, time: 86400.0000000000 ** INFO : In waq_wri_couple_files: # 25, time: 90000.0000000000 ** INFO : In waq_wri_couple_files: # 26, time: 93600.0000000000 ** INFO : In waq_wri_couple_files: # 27, time: 97200.0000000000 ** INFO : In waq_wri_couple_files: # 28, time: 100800.000000000 ** INFO : In waq_wri_couple_files: # 29, time: 104400.000000000 ** INFO : In waq_wri_couple_files: # 30, time: 108000.000000000 ** INFO : In waq_wri_couple_files: # 31, time: 111600.000000000 ** INFO : In waq_wri_couple_files: # 32, time: 115200.000000000 ** INFO : In waq_wri_couple_files: # 33, time: 118800.000000000 ** INFO : In waq_wri_couple_files: # 34, time: 122400.000000000 ** INFO : In waq_wri_couple_files: # 35, time: 126000.000000000 ** INFO : In waq_wri_couple_files: # 36, time: 129600.000000000 ** INFO : In waq_wri_couple_files: # 37, time: 133200.000000000 ** INFO : In waq_wri_couple_files: # 38, time: 136800.000000000 ** INFO : In waq_wri_couple_files: # 39, time: 140400.000000000 ** INFO : In waq_wri_couple_files: # 40, time: 144000.000000000 ** INFO : In waq_wri_couple_files: # 41, time: 147600.000000000 ** INFO : In waq_wri_couple_files: # 42, time: 151200.000000000 ** INFO : In waq_wri_couple_files: # 43, time: 154800.000000000 ** INFO : In waq_wri_couple_files: # 44, time: 158400.000000000 ** INFO : In waq_wri_couple_files: # 45, time: 162000.000000000 ** INFO : In waq_wri_couple_files: # 46, time: 165600.000000000 ** INFO : In waq_wri_couple_files: # 47, time: 169200.000000000 ** INFO : In waq_wri_couple_files: # 48, time: 172800.000000000 ** INFO : In waq_wri_couple_files: # 49, time: 176400.000000000 ** INFO : In waq_wri_couple_files: # 50, time: 180000.000000000 ** INFO : In waq_wri_couple_files: # 51, time: 183600.000000000 ** INFO : In waq_wri_couple_files: # 52, time: 187200.000000000 ** INFO : In waq_wri_couple_files: # 53, time: 190800.000000000 ** INFO : In waq_wri_couple_files: # 54, time: 194400.000000000 ** INFO : In waq_wri_couple_files: # 55, time: 198000.000000000 ** INFO : In waq_wri_couple_files: # 56, time: 201600.000000000 ** INFO : In waq_wri_couple_files: # 57, time: 205200.000000000 ** INFO : In waq_wri_couple_files: # 58, time: 208800.000000000 ** INFO : In waq_wri_couple_files: # 59, time: 212400.000000000 ** INFO : In waq_wri_couple_files: # 60, time: 216000.000000000 ** INFO : In waq_wri_couple_files: # 61, time: 219600.000000000 ** INFO : In waq_wri_couple_files: # 62, time: 223200.000000000 ** INFO : In waq_wri_couple_files: # 63, time: 226800.000000000 ** INFO : In waq_wri_couple_files: # 64, time: 230400.000000000 ** INFO : In waq_wri_couple_files: # 65, time: 234000.000000000 ** INFO : In waq_wri_couple_files: # 66, time: 237600.000000000 ** INFO : In waq_wri_couple_files: # 67, time: 241200.000000000 ** INFO : In waq_wri_couple_files: # 68, time: 244800.000000000 ** INFO : In waq_wri_couple_files: # 69, time: 248400.000000000 ** INFO : In waq_wri_couple_files: # 70, time: 252000.000000000 ** INFO : In waq_wri_couple_files: # 71, time: 255600.000000000 ** INFO : In waq_wri_couple_files: # 72, time: 259200.000000000 ** INFO : In waq_wri_couple_files: # 73, time: 262800.000000000 ** INFO : In waq_wri_couple_files: # 74, time: 266400.000000000 ** INFO : In waq_wri_couple_files: # 75, time: 270000.000000000 ** INFO : In waq_wri_couple_files: # 76, time: 273600.000000000 ** INFO : In waq_wri_couple_files: # 77, time: 277200.000000000 ** INFO : In waq_wri_couple_files: # 78, time: 280800.000000000 ** INFO : In waq_wri_couple_files: # 79, time: 284400.000000000 ** INFO : In waq_wri_couple_files: # 80, time: 288000.000000000 ** INFO : In waq_wri_couple_files: # 81, time: 291600.000000000 ** INFO : In waq_wri_couple_files: # 82, time: 295200.000000000 ** INFO : In waq_wri_couple_files: # 83, time: 298800.000000000 ** INFO : In waq_wri_couple_files: # 84, time: 302400.000000000 ** INFO : In waq_wri_couple_files: # 85, time: 306000.000000000 ** INFO : In waq_wri_couple_files: # 86, time: 309600.000000000 ** INFO : In waq_wri_couple_files: # 87, time: 313200.000000000 ** INFO : In waq_wri_couple_files: # 88, time: 316800.000000000 ** INFO : In waq_wri_couple_files: # 89, time: 320400.000000000 ** INFO : In waq_wri_couple_files: # 90, time: 324000.000000000 ** INFO : In waq_wri_couple_files: # 91, time: 327600.000000000 ** INFO : In waq_wri_couple_files: # 92, time: 331200.000000000 ** INFO : In waq_wri_couple_files: # 93, time: 334800.000000000 ** INFO : In waq_wri_couple_files: # 94, time: 338400.000000000 ** INFO : In waq_wri_couple_files: # 95, time: 342000.000000000 ** INFO : In waq_wri_couple_files: # 96, time: 345600.000000000 ** INFO : In waq_wri_couple_files: # 97, time: 349200.000000000 ** INFO : In waq_wri_couple_files: # 98, time: 352800.000000000 ** INFO : In waq_wri_couple_files: # 99, time: 356400.000000000 ** INFO : In waq_wri_couple_files: # 100, time: 360000.000000000 ** INFO : In waq_wri_couple_files: # 101, time: 363600.000000000 ** INFO : In waq_wri_couple_files: # 102, time: 367200.000000000 ** INFO : In waq_wri_couple_files: # 103, time: 370800.000000000 ** INFO : In waq_wri_couple_files: # 104, time: 374400.000000000 ** INFO : In waq_wri_couple_files: # 105, time: 378000.000000000 ** INFO : In waq_wri_couple_files: # 106, time: 381600.000000000 ** INFO : In waq_wri_couple_files: # 107, time: 385200.000000000 ** INFO : In waq_wri_couple_files: # 108, time: 388800.000000000 ** INFO : In waq_wri_couple_files: # 109, time: 392400.000000000 ** INFO : In waq_wri_couple_files: # 110, time: 396000.000000000 ** INFO : In waq_wri_couple_files: # 111, time: 399600.000000000 ** INFO : In waq_wri_couple_files: # 112, time: 403200.000000000 ** INFO : In waq_wri_couple_files: # 113, time: 406800.000000000 ** INFO : In waq_wri_couple_files: # 114, time: 410400.000000000 ** INFO : In waq_wri_couple_files: # 115, time: 414000.000000000 ** INFO : In waq_wri_couple_files: # 116, time: 417600.000000000 ** INFO : In waq_wri_couple_files: # 117, time: 421200.000000000 ** INFO : In waq_wri_couple_files: # 118, time: 424800.000000000 ** INFO : In waq_wri_couple_files: # 119, time: 428400.000000000 ** INFO : In waq_wri_couple_files: # 120, time: 432000.000000000 ** INFO : In waq_wri_couple_files: # 121, time: 435600.000000000 ** INFO : In waq_wri_couple_files: # 122, time: 439200.000000000 ** INFO : In waq_wri_couple_files: # 123, time: 442800.000000000 ** INFO : In waq_wri_couple_files: # 124, time: 446400.000000000 ** INFO : In waq_wri_couple_files: # 125, time: 450000.000000000 ** INFO : In waq_wri_couple_files: # 126, time: 453600.000000000 ** INFO : In waq_wri_couple_files: # 127, time: 457200.000000000 ** INFO : In waq_wri_couple_files: # 128, time: 460800.000000000 ** INFO : In waq_wri_couple_files: # 129, time: 464400.000000000 ** INFO : In waq_wri_couple_files: # 130, time: 468000.000000000 ** INFO : In waq_wri_couple_files: # 131, time: 471600.000000000 ** INFO : In waq_wri_couple_files: # 132, time: 475200.000000000 ** INFO : In waq_wri_couple_files: # 133, time: 478800.000000000 ** INFO : In waq_wri_couple_files: # 134, time: 482400.000000000 ** INFO : In waq_wri_couple_files: # 135, time: 486000.000000000 ** INFO : In waq_wri_couple_files: # 136, time: 489600.000000000 ** INFO : In waq_wri_couple_files: # 137, time: 493200.000000000 ** INFO : In waq_wri_couple_files: # 138, time: 496800.000000000 ** INFO : In waq_wri_couple_files: # 139, time: 500400.000000000 ** INFO : In waq_wri_couple_files: # 140, time: 504000.000000000 ** INFO : In waq_wri_couple_files: # 141, time: 507600.000000000 ** INFO : In waq_wri_couple_files: # 142, time: 511200.000000000 ** INFO : In waq_wri_couple_files: # 143, time: 514800.000000000 ** INFO : In waq_wri_couple_files: # 144, time: 518400.000000000 ** INFO : In waq_wri_couple_files: # 145, time: 522000.000000000 ** INFO : In waq_wri_couple_files: # 146, time: 525600.000000000 ** INFO : In waq_wri_couple_files: # 147, time: 529200.000000000 ** INFO : In waq_wri_couple_files: # 148, time: 532800.000000000 ** INFO : In waq_wri_couple_files: # 149, time: 536400.000000000 ** INFO : In waq_wri_couple_files: # 150, time: 540000.000000000 ** INFO : In waq_wri_couple_files: # 151, time: 543600.000000000 ** INFO : In waq_wri_couple_files: # 152, time: 547200.000000000 ** INFO : In waq_wri_couple_files: # 153, time: 550800.000000000 ** INFO : In waq_wri_couple_files: # 154, time: 554400.000000000 ** INFO : In waq_wri_couple_files: # 155, time: 558000.000000000 ** INFO : In waq_wri_couple_files: # 156, time: 561600.000000000 ** INFO : In waq_wri_couple_files: # 157, time: 565200.000000000 ** INFO : In waq_wri_couple_files: # 158, time: 568800.000000000 ** INFO : In waq_wri_couple_files: # 159, time: 572400.000000000 ** INFO : In waq_wri_couple_files: # 160, time: 576000.000000000 ** INFO : In waq_wri_couple_files: # 161, time: 579600.000000000 ** INFO : In waq_wri_couple_files: # 162, time: 583200.000000000 ** INFO : In waq_wri_couple_files: # 163, time: 586800.000000000 ** INFO : In waq_wri_couple_files: # 164, time: 590400.000000000 ** INFO : In waq_wri_couple_files: # 165, time: 594000.000000000 ** INFO : In waq_wri_couple_files: # 166, time: 597600.000000000 ** INFO : In waq_wri_couple_files: # 167, time: 601200.000000000 ** INFO : In waq_wri_couple_files: # 168, time: 604800.000000000 ** INFO : In waq_wri_couple_files: # 169, time: 608400.000000000 ** INFO : In waq_wri_couple_files: # 170, time: 612000.000000000 ** INFO : In waq_wri_couple_files: # 171, time: 615600.000000000 ** INFO : In waq_wri_couple_files: # 172, time: 619200.000000000 ** INFO : In waq_wri_couple_files: # 173, time: 622800.000000000 ** INFO : In waq_wri_couple_files: # 174, time: 626400.000000000 ** INFO : In waq_wri_couple_files: # 175, time: 630000.000000000 ** INFO : In waq_wri_couple_files: # 176, time: 633600.000000000 ** INFO : In waq_wri_couple_files: # 177, time: 637200.000000000 ** INFO : In waq_wri_couple_files: # 178, time: 640800.000000000 ** INFO : In waq_wri_couple_files: # 179, time: 644400.000000000 ** INFO : In waq_wri_couple_files: # 180, time: 648000.000000000 ** INFO : In waq_wri_couple_files: # 181, time: 651600.000000000 ** INFO : In waq_wri_couple_files: # 182, time: 655200.000000000 ** INFO : In waq_wri_couple_files: # 183, time: 658800.000000000 ** INFO : In waq_wri_couple_files: # 184, time: 662400.000000000 ** INFO : In waq_wri_couple_files: # 185, time: 666000.000000000 ** INFO : In waq_wri_couple_files: # 186, time: 669600.000000000 ** INFO : In waq_wri_couple_files: # 187, time: 673200.000000000 ** INFO : In waq_wri_couple_files: # 188, time: 676800.000000000 ** INFO : In waq_wri_couple_files: # 189, time: 680400.000000000 ** INFO : In waq_wri_couple_files: # 190, time: 684000.000000000 ** INFO : In waq_wri_couple_files: # 191, time: 687600.000000000 ** INFO : In waq_wri_couple_files: # 192, time: 691200.000000000 ** INFO : In waq_wri_couple_files: # 193, time: 694800.000000000 ** INFO : In waq_wri_couple_files: # 194, time: 698400.000000000 ** INFO : In waq_wri_couple_files: # 195, time: 702000.000000000 ** INFO : In waq_wri_couple_files: # 196, time: 705600.000000000 ** INFO : In waq_wri_couple_files: # 197, time: 709200.000000000 ** INFO : In waq_wri_couple_files: # 198, time: 712800.000000000 ** INFO : In waq_wri_couple_files: # 199, time: 716400.000000000 ** INFO : In waq_wri_couple_files: # 200, time: 720000.000000000 ** INFO : In waq_wri_couple_files: # 201, time: 723600.000000000 ** INFO : In waq_wri_couple_files: # 202, time: 727200.000000000 ** INFO : In waq_wri_couple_files: # 203, time: 730800.000000000 ** INFO : In waq_wri_couple_files: # 204, time: 734400.000000000 ** INFO : In waq_wri_couple_files: # 205, time: 738000.000000000 ** INFO : In waq_wri_couple_files: # 206, time: 741600.000000000 ** INFO : In waq_wri_couple_files: # 207, time: 745200.000000000 ** INFO : In waq_wri_couple_files: # 208, time: 748800.000000000 ** INFO : In waq_wri_couple_files: # 209, time: 752400.000000000 ** INFO : In waq_wri_couple_files: # 210, time: 756000.000000000 ** INFO : In waq_wri_couple_files: # 211, time: 759600.000000000 ** INFO : In waq_wri_couple_files: # 212, time: 763200.000000000 ** INFO : In waq_wri_couple_files: # 213, time: 766800.000000000 ** INFO : In waq_wri_couple_files: # 214, time: 770400.000000000 ** INFO : In waq_wri_couple_files: # 215, time: 774000.000000000 ** INFO : In waq_wri_couple_files: # 216, time: 777600.000000000 ** INFO : In waq_wri_couple_files: # 217, time: 781200.000000000 ** INFO : In waq_wri_couple_files: # 218, time: 784800.000000000 ** INFO : In waq_wri_couple_files: # 219, time: 788400.000000000 ** INFO : In waq_wri_couple_files: # 220, time: 792000.000000000 ** INFO : In waq_wri_couple_files: # 221, time: 795600.000000000 ** INFO : In waq_wri_couple_files: # 222, time: 799200.000000000 ** INFO : In waq_wri_couple_files: # 223, time: 802800.000000000 ** INFO : In waq_wri_couple_files: # 224, time: 806400.000000000 ** INFO : In waq_wri_couple_files: # 225, time: 810000.000000000 ** INFO : In waq_wri_couple_files: # 226, time: 813600.000000000 ** INFO : In waq_wri_couple_files: # 227, time: 817200.000000000 ** INFO : In waq_wri_couple_files: # 228, time: 820800.000000000 ** INFO : In waq_wri_couple_files: # 229, time: 824400.000000000 ** INFO : In waq_wri_couple_files: # 230, time: 828000.000000000 ** INFO : In waq_wri_couple_files: # 231, time: 831600.000000000 ** INFO : In waq_wri_couple_files: # 232, time: 835200.000000000 ** INFO : In waq_wri_couple_files: # 233, time: 838800.000000000 ** INFO : In waq_wri_couple_files: # 234, time: 842400.000000000 ** INFO : In waq_wri_couple_files: # 235, time: 846000.000000000 ** INFO : In waq_wri_couple_files: # 236, time: 849600.000000000 ** INFO : In waq_wri_couple_files: # 237, time: 853200.000000000 ** INFO : In waq_wri_couple_files: # 238, time: 856800.000000000 ** INFO : In waq_wri_couple_files: # 239, time: 860400.000000000 ** INFO : In waq_wri_couple_files: # 240, time: 864000.000000000 ** INFO : ** INFO : ** INFO : ** INFO : nr of netnodes ( ) : 4 ** INFO : nr of netlinks ( ) : 4 ** INFO : nr of flownodes ( ) : 2 ** INFO : nr of openbnd cells ( ) : 1 ** INFO : nr of 1D-flownodes ( ) : 0 ** INFO : model area (m2) : 0.1000000000E+01 ** INFO : model volume (m3) : 0.3600000000E+02 ** INFO : ** INFO : ** INFO : ** INFO : simulation period (s) : 864000.0000000000 ** INFO : nr of timesteps ( ) : 7207.0000000000 ** INFO : average timestep (s) : 119.8834466491 ** INFO : time inistep (s) : 0.4620000000 ** INFO : time setumod (s) : 0.1280000001 ** INFO : time furu (s) : 0.2289999999 ** INFO : time solve (s) : 0.2260000000 ** INFO : time setexternalforc. (s) : 0.0030000000 ** INFO : time setexternalfbnd. (s) : 0.1189999999 ** INFO : time steps (s) : 1.5420000000 ** INFO : time steps + plots (s) : 2.1750000000 ** INFO : fraction solve/steps ( ) : 0.1465629053 ** INFO : total/(dnt*ndx) (s) : 0.0001508950 ** INFO : av nr of cont. it s1it( ) : 0.0000000000 ** INFO : time transport [s] : 0.2930000000 ** INFO : time debug [s] : 0.0530000000 ** INFO : ** INFO : ** INFO : ** INFO : Computation started at: 17:18:37, 28-11-2017 ** INFO : Computation finished at: 17:18:39, 28-11-2017 ** INFO : ** INFO : MPI : no. ** INFO : OpenMP : unavailable. ** INFO : ** INFO : ** INFO : ** INFO : ** INFO : Closed file : DFM_DELWAQ_test_sed1\test_sed1.flo ** INFO : Closed file : DFM_DELWAQ_test_sed1\test_sed1.are ** INFO : Closed file : DFM_DELWAQ_test_sed1\test_sed1.vdf ** INFO : Closed file : DFM_DELWAQ_test_sed1\test_sed1.tau ** INFO : Closed file : test_sed1.map ** INFO : Closed file : test_sed1.mon ** INFO : Closed file : DFM_DELWAQ_test_sed1\test_sed1.vol