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A list of all pages that have property "Describe output parameters model" with value "See results of related publication by J. A. Czuba.". Since there have been only a few results, also nearby values are displayed.

Showing below up to 26 results starting with #1.

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List of results

  • Model:GEOtop  + (Please see: http://geotopmodel.github.io/geotop/)
  • Model:Instructed Glacier Model  + (Predict the evolution of glaciers, icefields, or ice sheets)
  • Model:GNE  + (Primary outputs: N, P, Si, and C yields and loads by river basin and nutrient form. Secondary outputs: Source attribution by nutrient form and main natural and anthropogenic inputs to watersheds. Total Suspended Solids are also predicted.)
  • Model:PsHIC  + (Produce 5 output files (ESRI ASCII format)Produce 5 output files (ESRI ASCII format):</br># HI.txt - pixel scale hypsometric integral;</br># max_elev.txt - the maximum elevation of the catchment flowing thorough each pixel;</br># Elev_Acc.txt - the sum of the elevation (m) of all the pixels flowing thorough each pixel;</br># flowacc.txt - Contributing area in pixels;</br></br>To change the names of the output files, edit the last section of the source code.</br># junctions.txt - how many of a pixel's 8 neighbors flow into it;any of a pixel's 8 neighbors flow into it;)
  • Model:MARSSIM  + (RAW image files of elevation and shaded relief. ASCII file of elevations at specified times. ASCII files of other state variables as desired at specified times. Iteration-by-iteration summary file)
  • Model:ROMSBuilder  + (ROMSBuilder creates the new component in hROMSBuilder creates the new component in home directory under "~/.cmt/components". It is safer not to edit the directory. Once a component is successfully created the next one goes relatively faster. To open the project user should go to "My Project > ROMSBuilder". The new project can only be seen by the owner. To share the project with the rest of the community please contact CSDMS.</br>Notes:</br>Please wait for ROMSBuilder to finish before creating the next component. Overall run time is almost an hour for the first component.</br>"Performance efficient mode" is not meant for ROMSBuilder, hence please avoid setting it on the tab dialogs.</br>Default configuration settings is always that of UPWELLING. Please edit the config values to run your new roms component.config values to run your new roms component.)
  • Model:GLUDM  + (Rasters containing the relative area of a specific land use in the future.)
  • Model:AeoLiS  + (Real-world grid cell surface area Wind velReal-world grid cell surface area</br>Wind velocity</br>Wind shear velocity</br>Wind direction</br>Bed level above reference</br>Water level above reference</br>Wave height</br>Equilibrium sediment concentration integrated over saltation height</br>Instantaneous sediment concentration integrated over saltation height</br>Instantaneous sediment flux</br>Sediment entrainment</br>Weights of sediment fractions</br>Weights of sediment fractions based on grain size distribution in the air</br>Weights of sediment fractions based on grain size distribution in the bed</br>Shear velocity threshold</br>Bed composition layer thickness</br>Moisure content</br>Salt content</br>Sediment mass in bed content Salt content Sediment mass in bed)
  • Model:BITM  + (Resultant barrier island configuration andResultant barrier island configuration and sediment distribution along the continental shelf as results of the effects of five different processes: reworking of the beach profile, inner-shelf sediment redistribution, overwash, laggonal deposition and aeolian sediment reworking.deposition and aeolian sediment reworking.)
  • Model:SPACE  + (Returns/updates Landlab grid fields: 'topographic__elevation' : Topographic surface elevation 'bedrock__elevation' : Bedrock surface elevation 'soil__depth' : Depth of alluvial layer on river bed 'sediment__flux' : Sediment flux out of each grid node)
  • Model:Avulsion  + (River positions with time)
  • Model:MRSAA  + (River profiles, sediment transport rates, alluvial cover depths and channel bed elevations.)
  • Model:OTTAR  + (River width)
  • Model:SPARROW  + (SPARROW is designed to describe the spatiaSPARROW is designed to describe the spatial patterns in water quality and the factors that affect it. SPARROW models are developed using mass balance constraints to quantify the relation between stream constituent load (the mass of the constituent being transported by the stream) and the sources and losses of mass in watersheds. Thus the models are inherently designed to predict load (mass per time) for all stream reaches in the modeling region. However, the predictions of stream load can be modified to provide a variety of water-quality metrics that can support various types of assessments.</br></br>The SPARROW prediction metrics include constituent yields, concentrations, and source contributions to stream loads: </br>*Constituent yields</br>*Constituent concentrations</br>*Source contributions to stream loadsions *Source contributions to stream loads)
  • Model:SWAN  + (SWAN can provide output on uniform, recti-SWAN can provide output on uniform, recti-linear spatial grids that are independent from the input grids and from the computational grid. In the computation with a curvi-linear computational grid, curvi-linear output grids are available in SWAN. This also holds for triangular meshes. An output grid has to be specified by the user with an arbitrary resolution, but it is of course wise to choose a resolution that is fine enough to show relevant spatial details. It must be pointed out that the information on an output grid is obtained from the computational grid by bi-linear interpolation (output always at computational time level). This implies that some inaccuracies are introduced by this interpolation. It also implies that bottom or current information on an output plot has been obtained by interpolating twice: once from the input grid to the computational grid and once from the computational grid to the output grid. If the input-, computational- and output grids are identical, then no interpolation errors occur.</br></br></br>In the regions where the output grid does not cover the computational grid, SWAN assumes output values equal to the corresponding exception value. For example, the default exception value for the significant wave height is -9. The exception values of output quantities can be changed by means of the QUANTITY command.</br></br></br>In nonstationary computations, output can be requested at regular intervals starting at a given time always at computational times. given time always at computational times.)
  • Model:Sedflux  + (Sediment properties that include (but are Sediment properties that include (but are not limited to) bulk density, grain size, porosity, and permeability. These are averaged over are user-specified vertical resolution (typically mm to cm).</br></br>Sea-floor properties that include slope, water depth, and sand fraction.ude slope, water depth, and sand fraction.)
  • Model:SRH-1D  + (Sediment transport rates, cross section geometry, bed material, flow and sediment output)
  • Model:NearCoM  + (See documentation.)
  • Model:GeoTiff Data Component  + (See documentation: https://bmi-geotiff.readthedocs.io)
  • Model:Topography Data Component  + (See documentation: https://bmi-topography.readthedocs.io)
  • Model:WAVEWATCH III Data Component  + (See documentation: https://bmi-wavewatch3.readthedocs.io)
  • Model:GridMET Data Component  + (See documentation: https://pymt-gridmet.readthedocs.io)
  • Model:Hilltop and hillslope morphology extraction  + (See included readme)
  • Model:FUNWAVE  + (See manual, that is uploaded.)
  • Model:Glimmer-CISM  + (See paper)
  • Model:River Network Bed-Material Sediment  + (See results of related publications by J. A. Czuba.)
  • Model:RiverMUSE  + (See the readme file.)
  • Model:OpenFOAM  + (See user manual)
  • Model:ADCIRC  + (See: (http://adcirc.org) *Screen Output (See: (http://adcirc.org) </br>*Screen Output (fort.6)</br>* General Diagnostic Output (fort.16)</br>* Iterative Solver ITPACKV 2D Diagnostic Output (fort.33)</br>* 3D Density, Temperature and/or Salinity at Specified Recording Stations (fort.41)</br>* 3D Velocity at Specified Recording Stations (fort.42)</br>* 3D Turbulence at Specified Recording Stations (fort.43)</br>* 3D Density, Temperature and/or Salinity at All Nodes in the Model Grid (fort.44)</br>* 3D Velocity at All Nodes in the Model Grid (fort.45)</br>* 3D Turbulence at All Nodes in the Model Grid (fort.46)</br>* Elevation Harmonic Constituents at Specified Elevation Recording Stations (fort.51)</br>* Depth-averaged Velocity Harmonic Constituents at Specified Velocity Recording Stations (fort.52)</br>* Elevation Harmonic Constituents at All Nodes in the Model Grid (fort.53)</br>* Depth-averaged Velocity Harmonic Constituents at All Nodes in the Model Grid (fort.54)</br>* Harmonic Constituent Diagnostic Output (fort.55)</br>* Elevation Time Series at Specified Elevation Recording Stations (fort.61)</br>* Depth-averaged Velocity Time Series at Specified Velocity Recording Stations (fort.62)</br>* Elevation Time Series at All Nodes in the Model Grid (fort.63)</br>* Depth-averaged Velocity Time Series at All Nodes in the Model Grid (fort.64)</br>* Hot Start Output (fort.67, fort.68)</br>* Atmospheric Pressure Time Series at Specified Meteorological Recording Stations (fort.71)</br>* Wind Velocity Time Series at Specified Meteorological Recording Stations (fort.72)</br>* Atmospheric Pressure Time Series at All Nodes in the Model Grid (fort.73)</br>* Wind Stress or Velocity Time Series at All Nodes in the Model Grid (fort.74)</br>* Depth-averaged Scalar Concentration Time Series at Specified Concentration Recording Stations (fort.81)</br>* Depth-averaged Scalar Concentration Time Series at All Nodes in the Model Grid (fort.83)</br>* Depth-averaged Density Fields at Specified Recording Stations (fort.91)</br>* Depth-averaged Density Fields at All Nodes in the Model Grid (fort.93)s at All Nodes in the Model Grid (fort.93))
  • Model:SWAT  + (See: https://swat.tamu.edu/)
  • Model:STWAVE  + (Selected Wave Spectra Selected Wave Parameters Wave Parameter Fields Breaker Index Fields Radiation Stress Gradient Fields)
  • Model:PIHMgis  + (Several state variables (soil moisture, groundwater table, stream head, interception, surface state and snow depth) and fluxes (3 components of evapotranspiration) 10 stream component fluxes for each reach, infiltration, recharge, lateral flux))
  • Model:Quad  + (Shoreline and alluvial-bedrock transition trajectories over time. Future versions of the model will include the profile evolution.)
  • Model:GENESIS  + (Shoreline position, breaking wave information, estimated longshore sand transport rates.)
  • Model:Bedrock Fault Scarp  + (Simple ascii files containing x and z coordinates of points at end of run. Optional output of figure in .eps format.)
  • Model:UEB  + (Snow melt)
  • Model:SNOWPACK  + (Snowpack creates various output files: * tSnowpack creates various output files:</br>* the current state of its soil and snow layers in ".sno" files;</br>* the current state of its hazard relevant data in ".haz" files;</br>* a time serie of snow profiles;</br>* a time serie of the meteorological data and fluxes as used in the model.ical data and fluxes as used in the model.)
  • Model:OTEQ  + (Solute concentrations as a function of space and time)
  • Model:WEPP  + (Storm, monthly, yearly, or average annual Storm, monthly, yearly, or average annual runoff, soil loss, and sediment yield from a hillslope profile. Spatial distribution of soil erosion and deposition on slope profiles. Graphical output available of 92 parameters from continuous model simulations (including precip, temperatures, runoff, soil loss, sediment yield, biomass production, residue cover, etc.). Soil output text file, water balance output text file, plant output text file, storm event output file, overland flow element summary line output file.and flow element summary line output file.)
  • Model:GIPL  + (Temperature distribution with depth Active Layer Depth Freezing/Thawing day)
  • Model:LONGPRO  + (Temporally evolving longitudinal profile and cross-sectional average flows of a 1D river)
  • Model:OverlandFlow  + (The Landlab OverlandFlow component outputsThe Landlab OverlandFlow component outputs data as Landlab fields - numpy arrays containing data with the associated CSDMS standard name, listed below:</br></br>'surface_water__depth' : NumPy array of length nnodes. Water depths at a given time step.</br>'surface_water__discharge' : NumPy array of length nlinks. Water discharge values at a given time step.</br>'water_surface__gradient' : NumPy array of length nlinks. Water surface gradient at a given time step.ter surface gradient at a given time step.)
  • Model:Permafrost Benchmark System  + (The PBS wraps ILAMB, which produces tabular and graphical statistics from a benchmark analysis. These outputs can be viewed in ILAMB, or downloaded to a user's local machine as a tarball.)
  • Model:WBMsed  + (The WBMplus model can output any variables used for the water balance and transport calculations. WBMsed unique output are: sediment-flux, over-bank water discharge, and all the BQART parameters.)
  • Model:SWEHR  + (The code outputs the following text files:The code outputs the following text files:</br>“topoout.txt” – elevation for each grid point at the end of the simulation</br>“depth.txt” – flow depth at each grid point at the end of the simulation</br>“uh.txt” – value of conserved variable UH at each grid point</br>“vh.txt” – value of conserved variable VH at each grid point</br>“ch.txt” – value of conserved variable CH at each grid point</br>“m.txt” – mass of sediment in the deposited layer at each grid point</br>“c.txt” – sediment concentration at each grid point</br>“vel.txt” – flow velocity at each grid point</br>“stage.txt” – time series data (time (s), flow depth, flow velocity, and sediment concentration) at the outlet pixel</br>“maxvel.txt” – maximum flow velocity recorded at each grid point throughout the simulation</br>“maxdepth.txt” -- maximum flow depth recorded at each grid point throughout the simulation</br>“saveflow.txt” – time series data (flow depth, flow velocity, sediment concentration) at user specified grid points</br>“topomovie.txt” – elevation data at different times throughout the simulation (specified in the code by “printinterval”)</br>“depthmovie.txt” – flow depth at different times throughout the simulation</br>“velocitymovie.txt” – flow velocity at different times throughout the simulation</br>“cmovie.txt” – sediment concentration at different times throughout the simulation</br>“Mmovie.txt” – mass of sediment in the deposited layer at different times throughout the simulation different times throughout the simulation)
  • Model:CMIP  + (The component provides monthly temperature data in degrees Celcius. Within the CSDMS framework, the component generates an NetCDF file of a stacked grid of monthly temperatures over the specified region.)
  • Model:DR3M  + (The computed outflow from any flow plane, The computed outflow from any flow plane, pipe, or channel segment for each storm period may be written to the output file or to the WDM file. A summary of the measured and simulated rainfall, runoff, and peak flows is written to the output file. A flat file containing the storm rainfall, measured flow (if available), and simulated flow at user selected sites can be generated. A flat file for each storm containing the total rainfall, the measured peak flow (if available), and the simulated peak flow for user-selected sites can be generated. for user-selected sites can be generated.)
  • Model:CruAKTemp  + (The data component provides monthly temperature as a NetCDF file for the region of Alaska)
  • Model:WRF-Hydro  + (The following output files are available tThe following output files are available to the user, depending on their run configuration:</br>1. Land surface model output</br>2. Land surface diagnostic output</br>3. Streamflow output at all channel reaches/cells</br>4. Streamflow output at forecast points or gage reaches/cells</br>5. Streamflow on the 2D high resolution routing grid (gridded channel routing only)</br>6. Terrain routing variables on the 2D high resolution routing grid</br>7. Lake output variables</br>8. Ground water output variables</br>9. A text file of streamflow output at either forecast points or gage locations</br>For a detailed table of each variable</br>contained within each output file, see the WRF-Hydro Output Variable Matrix V5 located on our website</br>https://ral.ucar.edu/projects/wrf_hydro/technical-description-user-guidewrf_hydro/technical-description-user-guide)
  • Model:1D Particle-Based Hillslope Evolution Model  + (The model can be customized to produce manThe model can be customized to produce many different kinds of output but, typically, the output consists of (i) h, a final hillslope profile; (ii) h_diffs, a vector which summarizes how the profile changed over the duration of the simulation; and (iii) a vector expressing the fluxes of particles through a site along the hillslope.</br></br>However, the same code can be used to produce a video of the hillslope evolution, a vector containing the absolute difference between the hillslope profile and a reference profile, and many other observables of interest.e, and many other observables of interest.)