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.

Search by property

A list of all pages that have property "One-line model description" with value "Pixel scale Area-Slope equation calculator". Since there have been only a few results, also nearby values are displayed.

Showing below up to 26 results starting with #1.

View (previous 50 | next 50) (20 | 50 | 100 | 250 | 500)


List of results

  • Model:NearCoM  + (Nearshore Community Model)
  • Model:Nitrate Network Model  + (Nitrate and organic carbon dynamics on a wetland-river network)
  • Model:PerronNLDiffuse  + (Nonlinear diffusion, following Perron (2011).)
  • Model:NormalFault  + (NormalFault implements relative rock motion due to a normal fault.)
  • Model:Elv-GST  + (Numerical 1D research code Elv applied to gravel-sand transitions)
  • Model:SBEACH  + (Numerical Model for Simulating Storm-Induce Beach Change)
  • Model:Cliffs  + (Numerical model to compute tsunami propagation and runup on land in the shallow-water approximation)
  • Model:OGGM  + (OGGM is a modular open source model for glacier dynamics)
  • Model:Oceananigans.jl  + (Oceananigans.jl is a fast and friendly ocean-flavored Julia software for simulating incompressible fluid dynamics in Cartesian and spherical shell domains on CPUs and GPUs.)
  • Model:OTTAR  + (Ode To Transient (Ancho de los) Rivers: Transient evolution of river-channel width in response to river discharge and bank and sediment properties.)
  • Model:OTEQ  + (One-Dimensional Transport with Equilibrium Chemistry (OTEQ): A Reactive Transport Model for Streams and Rivers)
  • Model:OTIS  + (One-Dimensional Transport with Inflow and Storage (OTIS): A Solute Transport Model for Streams and Rivers)
  • Model:SRH-1D  + (One-dimensional cross section based hydraulic and mobile-bed sediment transport model)
  • Model:OpenFOAM  + (Open Field Operation and Manipulation is a toolbox for the development of customized numerical solvers.)
  • Model:PHREEQC  + (PHREEQC version 3 is a computer program written in the C and C++ programming languages that is designed to perform a wide variety of aqueous geochemical calculations)
  • Model:PIHM  + (PIHM is a multiprocess, multi-scale hydrologic model.)
  • Model:Princeton Ocean Model (POM)  + (POM: Sigma coordinate coastal & basin circulation model)
  • Model:PISM  + (Parallel Ice Sheet Model, PISM)
  • Model:PSTSWM  + (Parallel Spectral Transform Shallow Water Model)
  • Model:ParFlow  + (Parallel, high-performance, integrated watershed model)
  • Model:SETTLE  + (Partical settling velocity solution)
  • Model:Non Local Means Filtering  + (Performs non-local means filtering of a DEM following Buades et al. (2005))
  • Model:Kudryavtsev Model  + (Permafrost Active Layer Thickness Model based on Kudryavtsev's parametrization)
  • Model:REF-DIF  + (Phase-resolving parabolic refraction-diffraction model for ocean surface wave propagation.)
  • Model:TOPMODEL  + (Physically based, distributed watershed model that simulates hydrologic fluxes of water through a watershed)
  • Model:PsHIC  + (Pixel-scale Hypsometric Integral Calculator)
  • Model:Point-Tidal-flat  + (Point Model for Tidal Flat Evolution model)
  • Model:CarboLOT  + (Population-ecology based model of shallow-ocean benthic carbonate accumulation)
  • Model:PRMS  + (Precipitation-Runoff Modeling System)
  • Model:WEPP  + (Process-based soil erosion by water at field/farm scale)
  • Model:DeltaSIM  + (Process-response model simulating the evolution and stratigraphy of fluvial dominated deltaic systems)
  • Model:PyDeCe  + (Python model for Dense Current forming eruptions (PyDeCe) is a tool for modeling the dense endmember of pyroclastic density currents generated either by impulsive column collapse or sustained fountaining eruptions.)
  • Model:Landlab  + (Python software framework for writing, assembling, and running 2D numerical models)
  • Model:SurfaceRoughness  + (Quantifies surface roughness with high-resolution topographic data by analyzing the local variability of surface normal vectors.)
  • Model:QDSSM  + (Quantitative Dynamic Sequence Stratigraphic Model)
  • Model:QTCM  + (Quasi-equilibrium Tropical Circulation Model)
  • Model:GSFLOW-GRASS  + (Quickly generates input files for and runs GSFLOW, and visualizes the output)
  • Model:ROMSBuilder  + (ROMSBuilder is a CCA-CSDMS Modeling Tool (CMT) compliant component that creates another CMT compliant ROMS component. The new ROMS component is build as per the C-preprocessing options that defines a particular ROMS application.)
  • Model:FractionalNoises1D  + (Read note in extended description. 1D fractional-noise generation with Fourier-filtering method)
  • Model:Spirals1D  + (Read note in extended description. 1D model of spiral troughs on Mars)
  • Model:FractionalNoises2D  + (Read note in extended description. 2D Gaussian fractional-noise generation with Fourier-filtering method)
  • Model:LavaFlow2D  + (Read note in extended description. 2D radially symmetric lava flow model)
  • Model:ADI-2D  + (Read note in extended description. Advection Diffusion Implicit (ADI) method for solving 2D diffusion equation)
  • Model:Coupled1D  + (Read note in extended description. Coupled 1D bedrock-alluvial channel evolution)
  • Model:FillinPitsFlatsDEM  + (Read note in extended description. Filling in pits and flats in a DEM)
  • Model:FTCS2D  + (Read note in extended description. Forward Time Centered Space (FTCS) method for 2D diffusion equation)
  • Model:FTCS2D-TerraceDiffusion  + (Read note in extended description. Forward Time Centered Space (FTCS) method for 2D Terrace diffusion)
  • Model:FTCS1D-NonLinear  + (Read note in extended description. Forward Time Centered Space (FTCS) method for 1D nonlinear diffusion equation)
  • Model:Flex2D  + (Read note in extended description. Fourier filtering in 2D while solving the flexure equation)
  • Model:Flex1D  + (Read note in extended description. Fourier filtering in 1D while solving the flexure equation)