Search by property

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:PsHIC  + (Two input files, all in ESRI ASCII format: # DEM # Flow direction grid (D8) To change the input files, edit lines 19 for DEM and line 20 for Flow-direction in the source code.)
• Model:OrderID  + (Two text files are required as input for a … Two text files are required as input for analysis of each vertical succession of strata in the following formats.</br></br>Vertical thickness and facies succession:</br><unit thickness (m)> <facies code (integer)></br><unit thickness (m)> <facies code (integer)></br>...</br><unit thickness (m)> <facies code (integer)></br>EOF</br></br>e.g. </br>0.61 9</br>0.05 5</br>0.52 1</br>...</br>1.21 3</br></br>Facies codes, colour coding and names:</br><Facies code 1 (integer)> <red (float)> <green (float)> <blue (float)> <facies name (string)></br><Facies code 2 (integer)> <red (float)> <green (float)> <blue (float)> <facies name (string)></br>...</br><Facies code n (integer)> <red (float)> <green (float)> <blue (float)> <facies name (string)></br></br>e.g. </br>1 0.55 0.32 0 clay</br>2 1 0.65 0 silt</br>3 0.93 0.91 0.8 fineSST</br>4 1 0.95 0.71 medSST</br>5 0.81 0.71 0.23 crsSST; <blue (float)> <facies name (string)> e.g. 1 0.55 0.32 0 clay 2 1 0.65 0 silt 3 0.93 0.91 0.8 fineSST 4 1 0.95 0.71 medSST 5 0.81 0.71 0.23 crsSST)
• Model:OptimalCycleID  + (Two text files are required as input for a … Two text files are required as input for analysis of each vertical succession of strata in the following formats.</br></br>Vertical thickness and facies succession: <unit thickness (m)> <facies code (integer)> <unit thickness (m)> <facies code (integer)> ... <unit thickness (m)> <facies code (integer)> EOF</br></br>e.g. 0.61 9 0.05 5 0.52 1 ... 1.21 3</br></br>Facies codes, colour coding and names: <Facies code 1 (integer)> <red (float)> <green (float)> <blue (float)> <facies name (string)> <Facies code 2 (integer)> <red (float)> <green (float)> <blue (float)> <facies name (string)> ... <Facies code n (integer)> <red (float)> <green (float)> <blue (float)> <facies name (string)></br></br>e.g. 1 0.55 0.32 0 clay 2 1 0.65 0 silt 3 0.93 0.91 0.8 fineSST 4 1 0.95 0.71 medSST 5 0.81 0.71 0.23 crsSSToat)> <blue (float)> <facies name (string)> e.g. 1 0.55 0.32 0 clay 2 1 0.65 0 silt 3 0.93 0.91 0.8 fineSST 4 1 0.95 0.71 medSST 5 0.81 0.71 0.23 crsSST)
• Model:OTTER  + (Typical inputs of a 1D river profile model (resolution, river length, model time, rock-uplift, erodibility, grain size characteristics))
• Model:Frost Model  + (USer-specified data on temperature distrib … USer-specified data on temperature distributions</br></br>We present the Frost model with a subsampled version of the CRU-NCEP reanalysis data for the region of Alaska. The geographical extent of this dataset has been reduced to greatly reduce the number of ocean, Aleatian Islands or Canadian pixels. The spatial resolution has been reduced by a factor of 13 in each direction, resulting in an effective pixel resolution of about 10km.</br></br>The data are monthly average temperatures for each month from January 1901 through December 2009.h from January 1901 through December 2009.)
• Model:GIPL  + (Upper Boundary (Air temperature) Lower Boundary (Temperature gradient) Initial conditions (Temperature distribution at initial time) Thermo-physical properties)
• Model:Permafrost Benchmark System  + (Users can upload ILAMB-compatible model outputs and benchmark datasets to the PBS. More information can be found in the PBS documentation, available at https://permamodel.github.io/pbs.)
• Model:SUSP  + (Various flow properties; sizes, densities and proportions of all grain fractions making up the active layer of the bed)
• Model:Cyclopath  + (Various text files defining initial conditions and parameter values)
• Model:GRLP  + (Water discharge inputs, sediment discharge inputs, base-level change, along-channel sources/sinks of sediment, grid of downstream distances)

• Model:Detrital Thermochron  + (Watershed hypsometry and detrital ages)

• Model:OlaFlow  + (Wave height, wave period, wave theory, water depth See: waveDict in Reference folder)
• Model:LITHFLEX2  + (Width of loading element (m), value for flexural rigidity (Nm), Number of loading events, Number of loading elements for event J (position, height (m) of loading element, density (kg/m3)))
• Model:LITHFLEX1  + (Width of loading element (meters), value for flexural rigidity (Nm), number of nodes describing baseline position, number of loading events, number of loading elements for event, number of hidden load elements.)
• Model:Point-Tidal-flat  + (Wind speed, storm duration, sediment characteristics, tidal currents)
• Model:BOM  + (Wind, rivers, submerged inlets, lateral open boundaries, surface heat flux, a limited number of numerical schemes can be chosen, ...)
• Model:SINUOUS  + (X,Y coordinates of centerline, hydrologic and sedimentary parameters, as detailed in the model documentation)
• Model:Bing  + (Yield/shear strength, viscosity, bulk density, shape of failed material; bathymetry)
• Model:Cross Shore Sediment Flux  + (You can vary the initial slope, wave periods, wave heights, and sediment fall velocity (a proxy for sediment size).)
• Model:GISKnickFinder  + (You need a DEM, a watershed outline (shape … You need a DEM, a watershed outline (shapefile), and a point shapefile identifying the top of the streams you are interested in. You also need to input a curvature threshold value and a drainage area threshold value. The curvature threshold is the key to identifying knickpoints (if it is too low you will not see very many knicks, and if it is too high you will identify too many). The drainage area threshold is used to exclude knickpoints that are not in the main channel you are interested in.in the main channel you are interested in.)
• Model:SedFoam-2.0  + (alpha,Ua, Ub, p, Theta, k, epsilon, omega)