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From CSDMS
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:DeltaBW + (--)
- Model:DeltaNorm + (--)
- Model:DepDistTotLoadCalc + (--)
- Model:DredgeSlotBW + (--)
- Model:FallVelocity + (--)
- Model:GSDCalculator + (--)
- Model:GravelSandTransition + (--)
- Model:RecircFeed + (--)
- Model:RiverWFRisingBaseLevelNormal + (--)
- Model:RouseVanoniEquilibrium + (--)
- Model:SteadyStateAg + (--)
- Model:SubsidingFan + (--)
- Model:SuspSedDensityStrat + (--)
- Model:WPHydResAMBL + (--)
- Model:WRF + (--)
- Model:SWMM + (--)
- Model:DynEarthSol3D + (--)
- 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)