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A list of all pages that have property "Describe numerical limitations" with value "The model is abstract.". Since there have been only a few results, also nearby values are displayed.

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  • Model:MARSSIM  + (Runs with grid sizes greater than about 600x600 may require many days on a PC. Model assumes fluvial streams have gradients determined by steady-state transport. Depositional stratigraphy not modeled.)
  • Model:SBEACH  + (SBEACH is an empirically based model that SBEACH is an empirically based model that was developed for sandy beaches with uniform representative grain sized in the range of 0.2 to 0.42 mm. SBEACH should be tested or calibrated using data from beach profile surveyed before and after storms on the project coast.ore and after storms on the project coast.)
  • Model:PHREEQC  + (See 'Description of Input and Examples for PHREEQC Version 3 - A computer program for speciation, batch-reaction, one-dimensional transport, and inverse geochemical calculations'.)
  • Model:WRF-Hydro  + (See WRF-Hydro Technical Description https://ral.ucar.edu/projects/wrf_hydro/technical-description-user-guide)
  • Model:EstuarineMorphologyEstimator  + (See article: https://doi.org/10.3390/rs10121915)
  • Model:Chi analysis tools  + (See documentation. The major limitation is computational time. This can be alleviated with sensible selection of module parameters. See documentation for guidance.)
  • Model:TIN-based Real-time Integrated Basin Simulator (tRIBS)  + (See https://tribshms.readthedocs.io/en/latest/)
  • Model:SPHYSICS  + (See manual)
  • Model:Nitrate Network Model  + (See related publication by J. A. Czuba.)
  • Model:River Network Bed-Material Sediment  + (See related publications by J. A. Czuba.)
  • Model:FwDET  + (See: Version 2.0: Cohen et al. (2019), TheSee:</br>Version 2.0: Cohen et al. (2019), The Floodwater Depth Estimation Tool (FwDET v2.0) for Improved Remote Sensing Analysis of Coastal Flooding. Natural Hazards and Earth System Sciences (NHESS)</br> </br>Version 1.0: Cohen, S., G. R. Brakenridge, A. Kettner, B. Bates, J. Nelson, R. McDonald, Y. Huang, D. Munasinghe, and J. Zhang (2017), Estimating Floodwater Depths from Flood Inundation Maps and Topography. Journal of the American Water Resources Association (JAWRA):1–12. Water Resources Association (JAWRA):1–12.)
  • Model:GRLP  + (Semi-implicit solution can decrease in accuracy for extremely long (hundreds of millions of years for typical input parameters) time steps)
  • Model:PIHM  + (Solver is efficient and accurate for very stiff systems of equations)
  • Model:FuzzyReef  + (Some of the fuzzy logic methods do not proSome of the fuzzy logic methods do not produce unique results as there are a variety of method choices that best 'match' test data. For example, the user can choose a variety of aggregation methods to calculate final carbonate facies and productivity values. carbonate facies and productivity values.)
  • Model:AR2-sinuosity  + (Some parameter values result in channels that self-intersect. The code outputs both the raw centerline and a simplified centerline with self-intersections removed.)
  • Model:IceFlow  + (Some time step limitations due to the *semi* implicit nature of the code)
  • Model:Cliffs  + (Subject to CFL stability condition. Sharp depth changes can cause instability even with low Courant numbers. Pre-processing with depth_ssl is recommended (see Cliffs User Manual at http://arxiv.org/abs/1410.0753 ))
  • Model:TUGS  + (TUGS was developed with a fairly low budget, and thus, bugs may still exist. There are, however, no known numerical limitations at this point.)
  • Model:SWEHR  + (The Courant number must be less than 1 at all times to maintain stability.)
  • Model:OceanWaves  + (The calculations assume the waves are wind waves with periods in the range of 0-~30 s. If the waves are much larger or produced by a different mechanism, the calculations are not likely to be accurate.)
  • Model:Tracer dispersion calculator  + (The elevation specific equation of mass coThe elevation specific equation of mass conservation is integrated with the Euler method. Thus, the user should carefully choose the spatial distance between computational nodes in the vertical and streamwise direction, as well as the temporal increment, to guarantee the numerical stability and mass conservation.numerical stability and mass conservation.)
  • Model:CHILD  + (The fluvial sediment transport equations aThe fluvial sediment transport equations are quasi-diffusive and typically have orders of magnitude spatial variations in rate coefficient (reflecting differences in water discharge), which makes the system of equations stiff. Small time steps are typically required, which can lead to long compute times for large meshes.ad to long compute times for large meshes.)
  • Model:Shoreline  + (The model cannot yet fully handle complex coastline geometries, such as those that cannot be represented (after rotation) by a single-valued function.)
  • Model:QDSSM  + (The model does not allow for compaction)
  • Model:CEM  + (The model handles complex-shaped coastlineThe model handles complex-shaped coastlines, such as cuspate-capes and spits. However, where the shoreline curvature becomes extreme (radius of curvature comparable to the cross-shore shoreface extent), as at the ends of spits, the assumptions of a locally rectilinear coordinate system break down, and sediment is conserved less rigorously locally. See Ashton and Murray (2006a) for details.See Ashton and Murray (2006a) for details.)
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