Property:Describe output parameters model

A 3D cube of model strata coded by water depth of deposition and thickness transported versus thickness deposited in-situ per time step  +

A plot, and/or the value of the NetCDF file at the designated cell  +

A sequence of grids that represent DEMs at different times in the evolution. Saved in RTS (RiverTools Sequence) format with RTI file for georeferencing.  +

A web page displaying skill scores for the models and plots (PNG) of the spatial distribution of model outputs versus benchmark data.  +

After infiltration occurs, the component returns an updated 'surface_water__depth' field, as well as an updated 'soil_water_infiltration__depth' field that tracks how much water has been infiltrated into the soil column.  +

Air Frost number  +

Although the model’s primary output product is channel discharge, all internal rate and state variables (soil moisture, for example) can also be written as output. In addition, all output can be written as grids, or time series at user-defined points or areas. The user has complete control over how output is written, thus minimising any waste of disk space or CPU time.  +

Amount of deflection of the crust as a function of horizontal position  +

Amount of deflection of the crust as a function of horizontal position.  +

Amount of the bed shear stress capable of transporting grains  +

Arc ASCII grids of topography and non-erodible basement.  +

Barrier elevation grid, cross-shore location of ocean and back-barrier shorelines, dune elevations, overwash flux, shoreface flux, shrub cover  +

Barrier island morphology and stratigraphy and migration rate. See User's Guide and Moore et al., 2010 for more details.  +

Barrier island, marsh, and bay morphology and stratigraphy over time. See User's Guide and Moore et al., 2010 for more details.  +

Benthic carbonate accumulation; sediment character and thickness; organism stocks and remains; environmental history; 2D-3D map graphics; graphs of stocks and vacant seafloor through time.  +

Bottom configuration at each time step.  +

Bottom wave orbital velocity. Also surface wave conditions if calculated from wind speed.  +

CREST outputs consist of several variables, including: *storage depths of the vegetation canopy, *the three soil layers, and two linear reservoirs, *relative change of the six reservoir levels representing actual evapotranspiration from the canopy and soil layers, *overland and interflow excess rain, * overland and interflow runoff.  +

CSV file of crustal deflection  +

CSV file of final bathymetry and deposit thickness for each grain size contained in the flow  +

CSV file of final bathymetry and deposit thickness for each grain size contained in the flow  +

Calibration algorithms, fit statistics.  +

Centerline and floodplain evolution through time, as well as hydraulic parameters as detailed in the model documentation  +

Channel centerlines and associated model parameters  +

Channel geometry; sediment export  +

Channel network configuration and morphology, marsh platform elevations, erosion and accretion rates, relevant geomorphological features  +

Characteristics of tree growth (stand biomass, stem count, leaf area, diamter) and characteristics of sediment transport (sediment flux in m4/m/yr, # of tree falls)  +

Chronostrat plots, maps, cross-sections, lithofacies thickness distributions  +

Cofactor matrix (*.mtx sparse matrix file; ASCII) Flexural response map (ASCII)  +

Compacted sediment porosity  +

Compute all carbonate system variables  +

Constant terminal settling velocity at STP  +

Critical shear stress for entrainment of a noncohesive grain from a mixed size-density bed  +

Critical shear stress for entrainment of a noncohesive grain from a homogenous bed  +

Cross-sectional average suspended load transport rates  +

Cross-sectional mean flow velocities, flow depths, bed shear stresses as a function of along-channel distance.  +

Current thickness, velocity, and D50 for active layer and in suspension.  +

Currents, salinity, temperature, ... all model variables.  +

DEM, Flow patterns, Inundation, Grainsize and others  +

DLBRM output includes, for every cell in the watershed grid, surface runoff to surface storage, infiltration to USZ, ET, ETP, percolation from USZ to LSZ, interflow from LSZ to surface storage, deep percolation from LSZ to groundwater storage, groundwater flow from groundwater storage to surface storage, surface moisture storage, USZ, and LSZ moisture storages, groundwater storage, and lateral flows from storages to adjacent cells for the surface (channel outflow), USZ, LSZ, and groundwater (Changsheng He and Thomas E. Croley II, 2007).  +

Dakotathon produces no output parameters; instead, it creates the standard Dakota output files '''dakota.out''' and '''dakota.dat'''.  +

Dampening effects of vegetation and snow on temperature Mean annual active layer thickness Mean annual temperature at the permafrost ground surface  +

Debris flow deposit thickness  +

Deep water significant wave height and period at each point under a hurricane.  +

Default: 3D Temperature and salinity field 3D Velocities 2D Sea Surface Height  +

Depend on different modules that are using, it can produce hydrodynamics, such as water velocity and depth; vertical density (3D); temperature plumes and salt wedge; water quality; sediment concentration and transport; underground water velocity field; wave parameters;  +

Depending on the flags indicated in the input file, typical flow quantities are stored to the file at the given time steps.<br> Velocities, Pressure, Concentration (of the particles).<br> Depending on the problems, some other quantities could be stored too.  +

Depending on the flags set in the "input.inp" file, flow properties such as velocity, pressure, particle concentration(s), particle deposit mass, bottom shear stress, kinetic and potential energy, dissipation rate, suspended particle mass, current front location, and etc are recorded at the given timesteps.  +

Depth, momentum on adaptive grid at specified output times. Time series at specified gauge locations. Maxima observed over full simulation on specified grid.  +

Discharge  +

Dynamic variables: # water energy # depositional (seafloor) slope Final output: # carbonate productivity rate # depositional facies  +

Elevation and slope arrays as well as optional information about bed cover and shear stress distributions, as well as block size distributions and incision rate records.  +

Elevation, Biomass, Accretion Rate, Erosion Rate, and other characteristics of every cell in domain. Also outputs spatially averaged statistics.  +

Elevation, drainage area, and related gridded information.  +

Estimated constituent loads  +

Estimated post-storm beach profile, cross-shore profile of: maximum wave height; maximum water elevation plus setup; volume change  +

Estimates of the erosional history and spatial patterns and model diagnostic plots.  +

Evolving 3D cellspace and 2D elevation map  +

Extent and thickness of the ice sheet, Velocity field, Temperature field, Water content field (temperate regions), Age of the ice, Isostatic displacement and temperature of the lithosphere.  +

Extent, and elevation, and cross-shore boundary locations of barrier, marsh (back-barrier and mainland), bay, and forest ecosystems; organic and mineral deposition; shoreline locations; dune elevations; overwash & shoreface fluxes  +

Filtered DEM: A new, filtered DEM in *.flt binary format. Noise: A *.flt binary format grid of the filtered noise.  +

Flow rates, depths, soil moisture, sediment fluxes, erosion/deposition, contaminant/nutrient fluxes and concentrations, groundwater levels, reservoir storages.  +

Flow velocities at N levels in the vertical, assuming a logarithmic velocity profile  +

Fluid velocity, pressure, temperature, salinity, concentrations, thermal flexes, and matrial fluxes at all nodes at any desired time. volumetric, energy, and mass balance at all types of boundaries and the entire boundary at any specified time. Br>For details refer to Yeh et al., 2005 Technical Report on WASH123D  +

For a single image: centerlines, widths, channel direction, curvatures For multiple images: (centerline) migration areas, erosion and accretion areas, cutoffs, cutoff statistics, channel belt boundaries, grid generation to map spatial changes, spacetime maps of changes in planform variables  +

Free-surface flow and wave action through time. Erosion and deposition through time. Optionally, compaction, including porosity reduction.  +

From wave heights to spectral data, see manual  +

Gaussian distribution of instantaneous turbulent fluid shear stresses at the bed  +

Geometry of river entrenchment thought time  +

Glacier thickness and elevation  +

Graphical Display and surface plot  +

Gravity flow velocity, Depth-integrated sediment load, down-slope sediment flux, flux convergence or divergence, erosion or deposition rate.  +

Grid of Sediment rate in m/day for specified grain size classes  +

Grid of deposition of different grains over time. The model generates postscript files of stratigraphic sections.  +

Gridding component provides ASCII and/or netCDF output of grid geometry.  +

Grids of topography  +

Grids of water surface elevation, discharge, bed elevation, and vegetation density values for each cell. Additionally, sand fraction of each vertical cell within a grid cell.  +

H, fluxes, discharge, catchment geom, etc, at all time steps, as welle as grid connectivity  +

HSPF produces a time history of the runoff flow rate, sediment load, and nutrient and pesticide concentrations, along with a time history of water quantity and quality at any point in a watershed. Simulation results can be processed through a frequency and duration analysis routine that produces output compatible with conventional toxicological measures (e.g., 96-hour LC50).  +

Hexagon DEM, flow direction, flow accumulation, stream grid, stream segment, stream order, stream confluence, subbasin, watershed boundary, etc.  +

Hydrologic information derived from DEM  +

Hydrologic model discretization, input files for GSFLOW, output files from GSFLOW (hydrologic model)  +

In addition to modeling the generation and transport of runoff flows, SWMM can also estimate the production of pollutant loads associated with this runoff. The following processes can be modeled for any number of user-defined water quality constituents: * dry-weather pollutant buildup over different land uses * pollutant washoff from specific land uses during storm events * direct contribution of rainfall deposition * reduction in dry-weather buildup due to street cleaning * reduction in washoff load due to BMPs * entry of dry weather sanitary flows and user-specified external inflows at any point in the drainage system * routing of water quality constituents through the drainage system * reduction in constituent concentration through treatment in storage units or by natural processes in pipes and channels  +

It can output local velocity, vorticity, concentration, stream-function, and all derivatives of velocity necessary to calculate dissipation, viscous momentum diffusion, kinetic energy flux, work by pressure forces, and change in kinetic energy. These quantities are written out in a binary file. It also has routines for calculating the local height profile and tip position of gravity currents and internal bores, which are outputted every time step and stored as ASCII txt files.  +

It outputs all the variables used in the advection-diffusion equation describing bed evolution for both shallow water wave assumptions (all labeled as *_s) and linear theory (labeled as *_lh).  +

Key indices, Mortalities, Consumption, Respiration, Niche overlap, Electivity, Search rates and Fishery forms.  +

Land cover and elevation prediction rasters under SLR conditions through 2100.  +

Long profile (x, z); output sediment discharge  +

Major quantities: mud floc concentration, flow velocity in longshelf and cross-shelf direction. Other quantities: TKE, turbulent dissipation rate, floc size (if floc dynamics turn on), bottom stress.  +

Mangrove properties and Delft3D-FM output  +

Many: pressure, saturation, temperature, energy fluxes, flow, etc.  +

Maps of geomorphology, discharge, deposition, isopachs, stratigraphic thickness, grain size, contour, subsidence, and environment  +

Marsh boundary - gives the position of the backbarrier marsh edge through time Shorelines - gives the position of the barrier shoreline through time step number - saves the surface morphology and stratigraphy for the model at each time step  +

Marsh depth, mudflat depth, mudflat width  +

Marsh elevation Pond area and location  +

Mass, atoms, landslide size, fluvial residence time, mixed mass and atoms fraction  +

Matlab variables, Matlab graphs  +

Matrices of: Water surface elevation; Water unit discharge and velocity field; Delta surface elevation and bathymetry; Stratigraphy (User can choose which time step to output)  +

Microsoft Excel tables  +

Model Interface Capabilities: There are three options available in the program interface: * The Hydrograph Prediction Option: This option allows the model to be run and hydrographs displayed. If a Topographic Index Map File is available, then a map button is displayed that allows the display of predicted simulation, either as a summary over all timesteps or animated. * The Sensitivity Analysis Option: This screen allows the sensitivity of the objective functions to changes of one or more of the parameters to be explored. * The Monte Carlo Analysis Option: In this option a large number of runs of the model can be made using uniform random samples of the parameters chosen for inclusion in the analysis. Check boxes can be used to choose the variables and objective functions to be saved for each run. The results file produced will be compatible with the GLUE analysis software package.  +