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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:LaMEM  + (--)
• Model:Underworld2  + (--)
• Model:ApsimX  + (--)
• Model:Icepack  + (--)
• Model:LavaFlow2D  + (--)
• Model:Oceananigans.jl  + (--)
• Model:Barrier3D  + (1) barrier3d-parameters.yaml: yaml-formatt … 1) barrier3d-parameters.yaml: yaml-formatted text file containing initial values for all static and dynamic variables</br></br>2) barrier3d-elevation.npy: Initial interior elevation grid</br></br>3) barrier3d-storms.npy: Stochastically generated sequence of storms (generated by randomly sampling from a list of synthetic storms)</br></br>4) barrier3d-dunes.npy: Initial height of dune cells</br></br>5) barrier3d-growthparam.npy: Alongshore varying growth rates for the dune domain</br></br>If desired, (3-5) can be generated within the model run script to create unique conditions for each run - e.g., instead of using the same storm history by drawing from the a single barrier3d-storms.npy file, a new storm series can be stochastically generated for each run. be stochastically generated for each run.)
• Model:FwDET  + (1. Flood inundation extent layer (shapefile or feature in a Geodatabase) 2. Digital Elevation Model (DEM; ArcGIS-supported raster formats))
• Model:RCPWAVE  + (2D bathymetric grid, offshore boundary wave height period and direction)
• Model:NEXRAD-extract  + (A NetCDF file, the name of the variable that you want to extract, and (optionally) a lat/lon position in which you would like to extract data from that variable)
• Model:ILAMB  + (A configuration file specifying models and variables to confront against benchmark data sets.)
• Model:HEBEM  + (A grid with initial elevation. Hydrologic … A grid with initial elevation. Hydrologic time step and geomorphic time step</br></br>Hydrologic paramters: average rainfall intensity, rainall duration, interstorm period, infiltration capacity, porosity, hydraulic conductivity, aquifer depth, specific yield, PET</br></br>Geomorphic parameters: baselevel lowering rate, diffusivity for hillslope processes, weathering rate, parameters for erosion and sediment transport models for erosion and sediment transport model)
• Model:FVshock  + (A long list of coefficient depending on the differential equations that are being solved and on the chosen closure relationships.)
• Model:TURBINS  + (A self-explanatory file "input.inp" should … A self-explanatory file "input.inp" should be set before running the code. </br>Flow and particle parameters such as Reynolds number, Peclet number, particle settling velocity(ies) can be set here. </br>Also, number of grid nodes, domain length, output file flags and simulation runtime, etc should be entered.simulation runtime, etc should be entered.)
• Model:Hydromad  + (A two-component structure of a soil moisture accounting (SMA) module and a routing or unit hydrograph module.)
• Model:AR2-sinuosity  + (AR2 model parameters, as defined in wrapper script)
• Model:Kudryavtsev Model  + (Air Temperature : seasonal range of air te … Air Temperature : seasonal range of air temperature </br>Snow parameters: winter-averaged Snow Thickness and Snow Density, thermal conductivity of snow</br>Vegetation parameters: Vegetation height, vegetation thermal conductivity</br>Soil properties: volumetric water content, heat capacity in frozen and thawed state, heat capacity in frozen and thawed state)
• Model:PHREEQC  + (All input for PHREEQC version 3 is defined … All input for PHREEQC version 3 is defined in keyword data blocks, each of which may have a series of identifiers for specific types of data.; See 'Description of Input and Examples for PHREEQC Version 3 - A computer program for speciation, batch-reaction, one-dimensional transport, and inverse geochemical calculations'.rt, and inverse geochemical calculations'.)
• Model:KnickZone-Picker  + (All input parameters are defined in a well-documented and commented Matlab parameter file. Only a Digital Elevation Model, preferable in GeoTIFF format is needed.)
• Model:LISFLOOD  + (All input that LISFLOOD requires are either in map or table format.)
• Model:WDUNE  + (Arc ASCII grids of topography and non-erodible basement. Program will create input grids also.)
• Model:Delft3D  + (Area schematization (mesh, bathymetry/topography, characteristics of structures, open boundary locations), process selection, initial conditions, forcings (boundary,atmospheric), time step, time frame, numerical settings, output options)
• Model:ROMSBuilder  + (Backend: ROMSBuilder is written in Python … Backend: ROMSBuilder is written in Python and the main classes are ComponentBuilder.py and ROMSComponentBuilder.py. Default inputs are provided through roms_builder_input.cfg file. The three required input set on the tab dialogs for creating the new ROMS component are,</br>Header file path, this is the path to your header (*.h) file. The other option is to enter value into the tab dialogs. ex. /home/csdms/sims/roms_builder/upwelling</br>Application name, this should be the name of your new ROMS Application and must be specified in UPPERCASE. ex. UPWELLING</br>New component name, this is the name of the new component. As bocca cannot have two components with the same name, every time you create a new component the name should be unique.a new component the name should be unique.)
• Model:Ecopath with Ecosim  + (Basic input requires: Habitat area, Biomass in habitat area, Production/biomass, Consumption/biomass, Ecotrophic efficiency, Production/consumption, Unassimilated consuption, detritus import)
• Model:Mrip  + (Basic parameters for a sediment transport … Basic parameters for a sediment transport model (grain size, efficiency coefficients, coefficient of friction, wave friction factor, density, etc) most are in there using values from the literature, but easily modified.</br></br>Flow. (Sinusoidal, steady or combined flows can be created, as well as natural flow data can be used.)</br>A random "turbulent" flow is imposed - this needs a magnitude.</br>Jump fraction - given distance sediment moves with flow - given distance sediment moves with flow)

• Model:STWAVE  + (Bathymetry Incident Wave Spectra Current Fields)

• Model:Landlab  + (Because this is a toolkit for model buildi … Because this is a toolkit for model building, there are no set input parameters. Rather, developers use the code to create their own models, with their own unique inputs. </br></br>The ModelParameterDictionary tool provides formatted ASCII input for model parameters. The I/O component also handles input of digital elevation models (DEMs) in standard ArcInfo ASCII format.s (DEMs) in standard ArcInfo ASCII format.)
• Model:MIDAS  + (Bed shear stress distribution and deriviti … Bed shear stress distribution and derivitives, Sediment transport parameters, Hiding function option (Komar / Egaziaroff), Saltation height option (Bridge / Einstein), Grain size and density distribution control parameters, Grain density values, Weight proportion of available bed material in each size-density fraction, Initial boundary condition (clear water inflow / equilibrium condition / well or not erosion or diposition in the dead of the reach)on or diposition in the dead of the reach))
• Model:RivMAP  + (Binary channel mask imagery (georeferencing optional). Imagery through time can be input to assess planform changes.)
• Model:ENTRAIN  + (Boundary Reynolds Number and Grain Size)
• Model:ENTRAINH  + (Boundary Reynolds Number, D50 of the bed, Shields Theta for D50 size fraction, median diameters of the other bed size fractions)
• Model:MarshPondModel  + (Channel geometry SLR rate Reference sediment concentration Parameters for sediment transport, organic accretion, pond dynamics, ditch dynamics)
• Model:River Erosion Model  + (Channel geometry (e.g. bank height/angle, width, longitudinal profile); bed grain size distribution; discharge time series; sediment input time series; bank soil parameters (critical shear stress and cohesion))
• Model:MCPM  + (Cross section width Channel length Tidal r … Cross section width</br>Channel length</br>Tidal range</br>Mud erodability</br>Mud critical shear stress</br>Settling velocity</br>Creep coefficient for unvegetated mud</br>Creep coefficient for vegetated mud (marsh)</br>Boundary suspended sediment concentration (during flood)</br>Maximum vegetation biomass</br>Minimum elevation for vegetation growth</br>Maximum elevation for vegetation growth</br>Parameters for organic sediment production</br>Rate of relative sea level riseproduction Rate of relative sea level rise)
• Model:LOGDIST  + (Cross-sectional average flow velocity and water depth)
• Model:SBM  + (Currently set up to modify the initial conditions (run time, wave height, current velocity, current dir., etc.) from within the source code.)
• Model:CAESAR Lisflood  + (DEM)
• Model:Caesar  + (DEM as ascii grid (output from arcGIS), Rainfall data as a space separated ascii file (straightforward list), Inputs of water/sediment in an ascii file. Other single value parameter inputs for grainsize, flow parameters, slope processes etc..)
• Model:HexWatershed  + (DEM raster and Hexagon shapefile, stream segment threshold)
• Model:FACET  + (DEM, National Hydrography Dataset Plus High Resolution)
• Model:GSSHA  + (DEM, land-use/land-cover, stream channels, … DEM, land-use/land-cover, stream channels, precipitation, soils, aquifer maps. These index maps are used to classify catchment parameters related to overland/channel flow, soil/aquifer hydraulic properties, soil erodibility, contaminant loadings, etc. Model setup is greatly enhanced by the use of the US Dept. of Defense Watershed Modeling System (WMS), which serves as an interface between GSSHA and Arc/Infoas an interface between GSSHA and Arc/Info)
• Model:GSFLOW-GRASS  + (DEM, rainfall, temperature)
• Model:Non Local Means Filtering  + (DEM: A DEM in *.flt binary format (as gene … DEM: A DEM in *.flt binary format (as generated by ARC GIS)</br>Search Window Radius: The distance around the centre cell in which to evaluate the means (in pixels).</br>Similarity Window Radius: The distance around neighbouring cells over which to calculate means (in pixels).</br>Degree of filtering: The weighting for the gaussian kernel controlling the strength of filtering and therefore the decay of weights as a function of distance from the centre of the kernel.of distance from the centre of the kernel.)
• Model:Lake-Permafrost with Subsidence  + (Daily average solar radiation for location (at surface).)
• Model:WEPP  + (Daily climate input (temperatures, precipi … Daily climate input (temperatures, precipitation depth, duration, Tp, Ip, wind info); slope input (distance downslope, slope at points, profile width, aspect); soil input (infiltration & erodibility parameters, soil layer depth, texture, organic matter, CEC, etc.; cropping/management input - plant growth parameters, residue decomposition parameters, tillage operation parameters, residue management parameters, dates of operations (planting, harvest, tillage, residue management, etc.); irrigation input - type of irrigation, date(s) of irrigation, application rates, etc.; channel parameters input - channel shape, width, slope, roughness, etc.; impoundment parameters input - type of impoundment (1. Drop Spillway 2. Perforated Riser 3. Culvert 4. Emergency Spillway or Open Channel 5. Rock Fill Check Dam 6. Filter Fence / Straw Bales / Trash Barriers 7. User Specified Stage-Discharge Relationship, parameter inputs specific to each impoundment type; watershed structure file - describes how all hillslopes, channels, and impoundments in a watershed are linked.s, and impoundments in a watershed are linked.)
• Model:DR3M  + (Daily precipitation, daily evapotranspirat … Daily precipitation, daily evapotranspiration, and short-interval precipitation are required. Short-interval discharge is required for the optimization option and to calibrate the model. These time series are read from a WDM file. Roughness and hydraulics parameters and sub-catchment areas are required to define the basin. Six parameters are required to calculate infiltration and soil-moisture accounting. Up to three rainfall stations may be used. Two soil types may be defined. A total of 99 flow planes, channels, pipes, reservoirs, and junctions may be used to define the basin.junctions may be used to define the basin.)
• Model:HSPF  + (Data needs for HSPF can be extensive. HSP … Data needs for HSPF can be extensive. HSPF is a continuous simulation</br>program and requires continuous data to drive the simulations. At a minimum,</br>continuous rainfall records are required to drive the runoff model and</br>additional records of evapotranspiration, temperature, and solar intensity</br>are desirable. A large number of model parameters can be specified although</br>default values are provided where reasonable values are available. HSPF is</br>a general-purpose program and special attention has been paid to cases where</br>input parameters are omitted. In addition, option flags allow bypassing of</br>whole sections of the program where data are not available. the program where data are not available.)
• Model:The TELEMAC system  + (Data that are used for TELEMAC model runs … Data that are used for TELEMAC model runs are:</br>a. Initial condition: A ‘CONSTANT ELEVATION’ is prescribed throughout the model. This initializes the free surface elevation at a constant value supplied by the keyword “INTIAL ELEVATION''.</br>b. Bathymetry.</br>c. Wind Data.</br>d. Tide Data</br>other parameters are given according to the modules are usedre given according to the modules are used)
• Model:SISV  + (Described in text files usr_input.txt and usr_IC.txt. Used to specify flow parameters (Re, Vs, ...), geometrical parameters (Lx, Ly, ...) and solver parameters (Nx, Ny))
• Model:GEOMBEST-Plus  + (Description: ''Note: See also the GEOMBEST … Description:</br>''Note: See also the GEOMBEST+ Users Guide'', section 6<br></br></br>A minimum of four excel files are required to run a GEOMBEST-Plus simulation: an “erosionresponse” file, an “accretionresponse” file, a “run#” file, and a “tract#” file. If the simulation involves a single coastal tract then the files must be titled “erosionresponse”, “accretionreponse”, “run1” file and “tract1.” Quasi-3D simulations require additional files with sequential numbers. For example a simulation involving 3 tracts within a littoral cell also requires a “run2” and “run3” file as well as a “tract2” and “tract3” file. These files must conform to the strict format outlined in the following sections. If you are running multiple simulations of the same tract, you can use the multiple input and output files to keep track of your simulations. Caution: Note that the run# and tract# files will have the same name (tract1, run1, etc., see below) for all simulations and so attention to organization is critical. We suggest noting the changes made in each simulation in a readme file and then moving this file, as well as the input and output folders for each simulation, to a unique folder having an identifying name. Our convention, for example, has been to name each run with using the date and run number on that date as the identifier, e.g., the first simulation run on February 20, 2010 would be titled 02_20_10_01and would be placed in a folder having this name.</br></br>'''6.1: “erosionresponse” file'''<br></br>'''6.2: “accretionresponse” file'''<br></br>'''6.3: “run#” file'''<br></br>'''6.4: “tract#” file'''t;br> '''6.3: “run#” file'''<br> '''6.4: “tract#” file''')
• Model:TauDEM  + (Digital elevation model)