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This page provides a simple browsing interface for finding entities described by a property and a named value. Other available search interfaces include the page property search, and the ask query builder.

List of results

• Model:Reservoir  + (The no-fail storage capacity and corresponding storage behaviour time series.)
• Model:GullyErosionProfiler1D  + (The output are elevation values that represent the gully channel profile.)
• Model:LTRANS  + (The output can ultimately be used to plot … The output can ultimately be used to plot and view the particles and compare the</br>outcomes of different model runs. There are two types of comma-delimited output files: para</br>and endfile. The para files are created periodically at set intervals throughout the running of the</br>program and contain the particle locations at the current time. The endfile file is created only at</br>the end of the program and contains information regarding each particles’ start location, end</br>location, and ending status.location, end location, and ending status.)
• Model:Hilltop flow routing  + (The output data is both plain text data files and .flt raster files containing the spatial location of the computed results.)
• Model:CEM  + (The output of the model consists of snapsh … The output of the model consists of snapshots of the coastline during its evolution. The model can be configured to write the resulting coastline at any point during the simulation. The output format of the coastline file is a custom binary formatted-file (the same format as the initial model input). Also, for convenience using with other software tools such as MATLAB, an ASCII-based file of the coastline shape can be written too. The model can also directly generate JPEG-formatted pictures of the coastline shape at any time during the simulation.e shape at any time during the simulation.)
• Model:Chi analysis tools  + (The outputs are i) For chi_m_over_n_analys … The outputs are</br>i) For chi_m_over_n_analysis.exe, a *.movern file that contains information about the goodness of fit of channel profiles to a series of linear segments as a function of the m/n ratio: this file is used to determine the best fit m/n ratio of a channel network. </br>ii) For chi_get_profiles.exe, a series of *.tree files which contain information about the best fit channel segments in chi-elevation space. This data can be used to infer erosion rates, tectonics, or variations in erodibility., tectonics, or variations in erodibility.)
• Model:HydroCNHS  + (The outputs of HydroCNHS are stored in a d … The outputs of HydroCNHS are stored in a data collector object, an attribute of HydroCNHS (e.g., model.dc). The main output is the daily streamflow at routing outlets. However, this data collector object will also contain other user-specified agent outputs as long as users use this data collector object in their ABM modules.ata collector object in their ABM modules.)
• Model:CVPM  + (The state of the system is periodically output to a binary file that can be read by the post-processing and visualization routines (see the CVPM modeling system user's guide).)
• Model:STORM  + (The windfield for a cyclone based on pressure distribution and radius to maximum winds (SI units).)
• Model:DHSVM  + (There are a number of different types of o … There are a number of different types of output that the model can produce. In short, the following possibilities are available:</br></br>DHSVM hydrologic output</br>* Default output (these files are always produced)</br>* Model state files</br>* Network flow files</br>* Travel time based hydrograph file</br>* Optional output files</br></br>Sediment Module output</br>* Default output (these files are always produced)</br>* Network flow files</br>* Optional output filesNetwork flow files * Optional output files)
• Model:ROMS  + (There are hundreds of output parameters and fields that are written to several NetCDF files.)
• Model:ChesROMS  + (There are hundreds of output parameters and fields that are written to several NetCDF files.)
• Model:CBOFS2  + (There are hundreds of output parameters and fields that are written to several NetCDF files.)
• Model:UMCESroms  + (There are hundreds of output parameters and fields that are written to several NetCDF files.)
• Model:TopoFlow-Channels-Diffusive Wave  + (This component computes the following vari … This component computes the following variables, as grids:</br> Q = discharge (m^3/s)</br> u = flow velocity (m/s)</br> d = flow depth (m)</br> f = friction factor (none)</br> Rh = hydraulic radius (m)</br> S_free = free-surface slope (m/m)</br>The user can choose which, if any, of these to save. Each may be saved as a grid sequence, indexed by time, in a netCDF file, at a specified sampling rate. Each may also be saved for a set of "monitored" grid cells, each specified as a (row,column) pair in a file with the name: <case_prefix>_outlets.txt. With this option, computed values are saved in a multi-column text file at a specified sampling rate. Each column in this file corresponds to a time series of values for a particular grid cell. For both options the sampling rate must no smaller than the process timestep. rate must no smaller than the process timestep.)
• Model:TopoFlow-Channels-Dynamic Wave  + (This component computes the following vari … This component computes the following variables, as grids:</br> Q = discharge (m^3/s)</br> u = flow velocity (m/s)</br> d = flow depth (m)</br> f = friction factor (none)</br> Rh = hydraulic radius (m)</br> S_free = free-surface slope (m/m)</br>The user can choose which, if any, of these to save. Each may be saved as a grid sequence, indexed by time, in a netCDF file, at a specified sampling rate. Each may also be saved for a set of "monitored" grid cells, each specified as a (row,column) pair in a file with the name: <case_prefix>_outlets.txt. With this option, computed values are saved in a multi-column text file at a specified sampling rate. Each column in this file corresponds to a time series of values for a particular grid cell. For both options the sampling rate must no smaller than the process timestep. rate must no smaller than the process timestep.)
• Model:TopoFlow-Channels-Kinematic Wave  + (This component computes the following vari … This component computes the following variables, as grids:</br> Q = discharge (m^3/s)</br> u = flow velocity (m/s)</br> d = flow depth (m)</br> f = friction factor (none)</br> Rh = hydraulic radius (m)</br> S_free = free-surface slope (m/m)</br>The user can choose which, if any, of these to save. Each may be saved as a grid sequence, indexed by time, in a netCDF file, at a specified sampling rate. Each may also be saved for a set of "monitored" grid cells, each specified as a (row,column) pair in a file with the name: <case_prefix>_outlets.txt. With this option, computed values are saved in a multi-column text file at a specified sampling rate. Each column in this file corresponds to a time series of values for a particular grid cell. For both options the sampling rate must no smaller than the process timestep. rate must no smaller than the process timestep.)
• Model:CellularFanDelta  + (Time series of 2D topography/bathymetry and water discharge. 3D stratigraphy grid (currently model is single grain-size, so stratigraphy only stores deposit age))
• Model:Delft3D  + (Time series of 2D/3D map data and selected point data, particle tracks)
• Model:TUGS  + (Time variation of longitudinal profile, sediment flux and grain size distributions of bedload, surface and subsurface sediment.)
• Model:Barrier Inlet Environment (BRIE) Model  + (Timeseries of: Overwash fluxes (m3/m/s) Inlet fluxes (m3/m/s) Shoreface toe location (m) Shoreline location (m) Back-barrier location (m) Barrier Height (m) Inlet locations alongshore (m))
• Model:PHREEQC  + (To many to list here, see ''Description of Input and Examples for PHREEQC Version 3 - A computer program for speciation, batch-reaction, one-dimensional transport, and inverse geochemical calculations'.)
• Model:PyDeltaRCM  + (Toggle on/off in input file: - PNG files of eta, stage, depth - grids of eta, stage, depth (as netCDF4) - grids of sand fraction in stratigraphy (as netCDF4))
• Model:TopoFlow  + (Too many to list here. Please see the HTML help system and the wiki pages for all of the process components.)
• Model:MODFLOW  + (Too many to mention here, see: http://water.usgs.gov/nrp/gwsoftware/modflow2000/modflow2000.html)

• Model:YANGs  + (Total load mass flux)

• Model:Area-Slope Equation Calculator  + (Two output maps ESRI ASCII format: # Alpha (coefficient); # Constant.)
• Model:SISV  + (Typical flow quantities: Velocities, Concentrations, Vorticity, Passive marker location)
• Model:OlaFlow  + (VOF, U, turbulence variables...)
• Model:Pllcart3d  + (Velocities and concentration fields of the particles are stored to binary files at given time steps.)
• Model:DELTA  + (Vertically-integrated flow velocities and bed elevations as functions of time and two horizontal dimensions)
• Model:2DFLOWVEL  + (Vertically-integrated flow velocities and water surface elevations as functions of time and two horizontal dimensions)
• Model:WOFOST  + (WOFOST simulates the growth of a specific … WOFOST simulates the growth of a specific crop and its interaction with the soil. Its main output variables consist of crop variables (like total biomass, yield, phenological development and leaf area index) and soil variables like soil water content. More recent versions of WOFOST also include the N/P/K amounts in the crop organs and soil.N/P/K amounts in the crop organs and soil.)
• Model:MCPM  + (Water level Water velocity Bed shear stress Suspended sediment concentration Bed elevation)
• Model:DepthDependentTaylorDiffuser  + (_info = { "bedrock__elevation": { … _info = {</br> "bedrock__elevation": {</br> "dtype": float,</br> "intent": "out",</br> "optional": False,</br> "units": "m",</br> "mapping": "node",</br> "doc": "elevation of the bedrock surface",</br> },</br> "soil__depth": {</br> "dtype": float,</br> "intent": "inout",</br> "optional": False,</br> "units": "m",</br> "mapping": "node",</br> "doc": "Depth of soil or weathered bedrock",</br> },</br> "soil__flux": {</br> "dtype": float,</br> "intent": "out",</br> "optional": False,</br> "units": "m^2/yr",</br> "mapping": "link",</br> "doc": "flux of soil in direction of link",</br> },</br> "soil_production__rate": {</br> "dtype": float,</br> "intent": "in",</br> "optional": False,</br> "units": "m/yr",</br> "mapping": "node",</br> "doc": "rate of soil production at nodes",</br> },</br> "topographic__elevation": {</br> "dtype": float,</br> "intent": "inout",</br> "optional": False,</br> "units": "m",</br> "mapping": "node",</br> "doc": "Land surface topographic elevation",</br> },</br> "topographic__slope": {</br> "dtype": float,</br> "intent": "out",</br> "optional": False,</br> "units": "m/m",</br> "mapping": "link",</br> "doc": "gradient of the ground surface",</br> },</br> }t of the ground surface", }, })
• Model:DetachmentLtdErosion  + (_info = { "surface_water__discharg … _info = {</br> "surface_water__discharge": {</br> "dtype": float,</br> "intent": "in",</br> "optional": False,</br> "units": "m**3/s",</br> "mapping": "node",</br> "doc": "Volumetric discharge of surface water",</br> },</br> "topographic__elevation": {</br> "dtype": float,</br> "intent": "inout",</br> "optional": False,</br> "units": "m",</br> "mapping": "node",</br> "doc": "Land surface topographic elevation",</br> },</br> "topographic__slope": {</br> "dtype": float,</br> "intent": "in",</br> "optional": True,</br> "units": "-",</br> "mapping": "node",</br> "doc": "gradient of the ground surface",</br> },</br> }t of the ground surface", }, })
• Model:SedFoam-2.0  + (alpha: sediment concentration Ua: sediment velocity Ub: fluid velocity p: fluid pressure Theta: granular temperature k: fluid kinetic energy epsilon/omega: fluid turbulent dissipation)
• Model:Caesar  + (ascii grids (readable into arcGIS) and goo … ascii grids (readable into arcGIS) and google earth images of: DEM, flow depth, surface grainsize, shear stress, vegetation cover, velocity.</br>Also time series of water discharge and sediment discharge (across 9 grainsizes) at user chosen interval.</br>Also visual output to AVI file. interval. Also visual output to AVI file.)
• Model:CrevasseFlow  + (averaged daily water discharge to lower reach of crevasse splay; averaged daily crevasse splay depth; averaged daily crevasse splay width)
• Model:ZoneTaxon  + (boolean: Indicates if the taxon is still … boolean: </br>Indicates if the taxon is still evolving. When `False` is returned,</br>this method will not be called for the taxon in subsequent stages in</br>the current model time step.<br></br>list of Taxon: </br>The children produced by the taxon at a given stage. The ``evolve``</br>method of child taxon will be called in stages following the stage</br>the child taxon was produced. An empty list indicates no child</br>taxon.roduced. An empty list indicates no child taxon.)
• Model:Zscape  + (change in topographic profile with time)
• Model:Meanderpy  + (channel centerlines; 3d model)
• Model:DeltaClassification  + (classification of groups of similar zones … classification of groups of similar zones within a deltasystem</br>code blocks that:</br></br>• loads in the shapefiles</br>• calculate the parameters for the network that both surround and drain the islands</br>• calculate the base metrics (e.g. perimeter, area, solidity, aspect ratio...)</br>• calculates maximum distance from the island center to the nearest water body</br>• estimates minimum, average and maximum widths of all network channels</br>• evaluates the fractal dimension of each delta island</br>• creates shapefiles based on the metrics calculated earlier in the code</br>• saves all metrics to an output file</br>• generates PCA and GeoSOM results from the island and channel metrics</br>• plots the U-matrix and dendrogram based on the GeoSOM resultsand dendrogram based on the GeoSOM results)
• Model:GreenAmptInfiltrationModel  + (cumulative infiltration, infiltration rate)
• Model:River Temperature Model  + (daily river temperature)
• Model:FVshock  + (depth, liquid and solid discharges along x and y. In the multi-layer version(under development), these are provided for each layer.)
• Model:MarshMorpho2D  + (elevation through time many other parameters can be saved during the simulations (e.g., velocity, suspended sediment concentration))
• Model:LinearDiffuser  + (elevation; slope gradient; soil unit discharge)
• Model:HEBEM  + (elevations of all nodes elevation changes of all nodes)
• Model:Equilibrium Calculator  + (equilibrium channel slope, width and depth … equilibrium channel slope, width and depth, bankfull discharge, point bar height, difference in elevation between eroding and depositing banks, channel migration rate, overbank deposition rates of sand and mud, volume fraction content of sand and mud in the floodplain.content of sand and mud in the floodplain.)
• Model:Gospl  + (evolving landscape, stratigraphy)