CMS-Flow:Features: Difference between revisions
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==Hard Bottom== | ==Hard Bottom== | ||
==Variable D50== | ==Variable D50== | ||
==Eddy Viscosity== | |||
Eddy Viscosity in CMS-Flow is calculated with a subgrid turbulence model. More information can be found [[CMS-Flow:Subgrid_Turbulence_Model|'''here''']]. | |||
='''Other Features'''= | ='''Other Features'''= |
Revision as of 20:46, 11 December 2009
Boundary Conditions
CMS-Flow has multiple types of boundary conditions which are listed and discussed below. All CMS-Flow boundary conditions are forced at the edges of the domain by use of cellstrings defined with the Surfacewater Modeling System.
Water Surface Elevation Forcing
Two types of Water Surface Elevation Forcing exist for CMS-Flow. Once a water surface elevation curve (or series of curves) is applied, the user is able to display the curve information graphically.
- Single value for all cells on a cellstring
- Multiple values on a cellstring (one for each cell)
Single Value
User creates a cellstring for the given boundary and defines a time-series curve. The value for each time on this curve is applied to all cells along the designated cellstring.
Multiple Values
User creates a cellstring for the given boundary and extracts multiple time-series curves from a dataset or database. Each cell along the cellstring is given its own time-series curve information. Examples are:
- Extraction of water surface elevation values from a larger domain solution (ie. Larger CMS-Flow or ADCIRC grid)
- Extraction of tidal constituent information from a tidal database, from which a water surface elevation curve can be generated.
Water Surface Elevation and Velocity Forcing
Users are able to extract both water surface elevations and velocity components from a larger domain solution (ie. Larger CMS-Flow or ADCIRC grid).
River Flow Forcing
User creates a cellstring for the given boundary, chooses a River Flow type for the cellstring, then creates a time-series curve of flow rates. NOTES:
- Total flow rate specified is divided between the total number of cells in the cellstring with each carrying a portion of the total.
- The sign of the flow rate curve is dependent on the direction of flow with respect to the origin (always lower-left hand corner of the grid). This guide should assist in proper assignment.
- Flow rate from the East - Negative value
- Flow rate from the West - Positive value
- Flow rate from the North - Negative value
- Flow rate from the South - Positive value
Salinity Concentration Forcing
If salinity transport is active for the simulation, the user has the ability to use existing hydrodynamic cellstrings in the interface in order to provide a time-series curve of salinity concentrations.
Global Forcing
There are two main types of global forcing available in CMS-Flow, wind and wave. Global forcing means that the forcing is applied on a cell-by-cell nature, rather than forcing along a boundary.
Wind Forcing
Temporally varying, spatially constant (ie. one value of wind applied for a given time to every computational cell in the domain.
- In the near future a variable wind will be allowed and an interface within the SMS will be provided.
Wave Forcing
Temporally and spatially varying.
- Wave forcing is generally provided by the user selecting to use the Steering Module within SMS. The mapping of wave data from wave grid to flow grid is automated during the course of the steering process.
- If a choice is made not to use the steering process, the user must provide several datasets of information which has been mapped to the flow grid geometery.
- Radiation stress gradient
- Wave height
- Wave period
- Wave direction
- Wave dissipation
Transport Options
Sediment Transport
Non-equilibrium Algorithm
The non-equilibrium sediment transport algorithm (NET) simulates non-cohesive, single size sediment transport and bed change using a Finite Volume method and includes advection, diffusion, hiding and exposure, and avalanching. NET sediment transport is calculated with a non-equilibrium bed-material (total load) formulation. In this approach, the suspended- and bed-load transport equations are combined into a single equation and thus there is one less empirical parameter to estimate (adaptation length).
Additional information on NET can be found here.
Total Load Algorithm
Salinity Transport
In many estuaries, the density gradients caused by spatial variations in salinity can be an important driving force in the circulation. Salinity is also a key water quality variable in estuaries, since it affects the chemical and biological processes. Salinity is simulated in the Coastal Modeling System (CMS) in a depth-averaged sense. This means that the estuary or body of water is assumed to be well mixed vertically and the salinity is constant over the water column.
The salinity transport equation is solved with an explicit, finite volume method. The advection term is discretized with upwind scheme, and the diffusion term is discretized with the standard central difference scheme.
Additional information on Salinity Transport in CMS-Flow can be found here.
Other Processes
Bottom Friction
Hard Bottom
Variable D50
Eddy Viscosity
Eddy Viscosity in CMS-Flow is calculated with a subgrid turbulence model. More information can be found here.
Other Features
Parallelization with OpenMP
Both Intel and AMD processors now are shipping chips with multiple cores/processors (henceforth referred to as "processors") available. CMS-Flow is now configured to make use of these extra processes that are available on newer machines.
Additional information on using Multiple Processors with CMS-Flow can be found here.
Units of Measurement
- Water Surface Elevation - meters ()
- Current Velocity - meters per second ()
- Flow Rate - cubic meters per second ()
- Salinity Concentration - parts per thousand ()