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[[de: Mathematisches Verfahren TRIM-3D]]
[[de: Mathematisches Verfahren TRIM-3D]]
==Short Description==
==Short Description==
The mathematical model TRIM-3D is based on the finite difference method. In contrast to the two-dimensional (depth-averaged) mathematical model [[Mathematical Model TRIM-2D|TRIM-2D]], TRIM-3D is a fully three-dimensional model. TRIM-3D was designed to solve several transient nonlinear partial differential equations (pde's). The model is actually used to study one ore more of the following physical processes:
The mathematical [[model]] [[Trim|TRIM]]-3D is based on the finite difference method. In contrast to the two-dimensional (depth-averaged) mathematical [[model]] [[Mathematical Model TRIM-2D|TRIM-2D]], [[Trim|TRIM]]-3D is a fully three-dimensional [[model]]. [[Trim|TRIM]]-3D was designed to solve several transient nonlinear partial differential equations (pde's). The [[model]] is actually used to study one ore more of the following physical processes:


# transport of water (conservation of the water mass)
# transport of water (conservation of the water mass)
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# transport of salinity (conservation of the dissolved salt mass)
# transport of salinity (conservation of the dissolved salt mass)


The model takes into account hydrodynamic pressure in the water body (non-hydrostatic pressure distribution). A simplifying hydrostatic approximation can be alternatively used. This approximation might be useful for natural systems with negligible vertical accelerations (compared with gravity).
The [[model]] takes into account hydrodynamic pressure in the water body (non-[[hydrostatic pressure]] distribution). A simplifying hydrostatic approximation can be alternatively used. This approximation might be useful for natural systems with negligible vertical accelerations (compared with gravity).


TRIM-3D was developed by Prof. V. Casulli (Trento University, Italy). In the framework of a scientific cooperation TRIM-3D has been successfully installed in the year 1996 at BAW-DHs computers. It has been integrated into BAW-DHs numerical modelling toolbox and is now used on a routine basis in the context of different real-world projects concerning estuarine flow and transport processes. Meanwhile the code of TRIM-3D has been optimized to improve performance on multiprocessor vector computers.
[[Trim|TRIM]]-3D was developed by Prof. V. Casulli (Trento University, Italy). In the framework of a scientific cooperation [[Trim|TRIM]]-3D has been successfully installed in the year 1996 at BAW-DHs computers. It has been integrated into BAW-DHs numerical modelling toolbox and is now used on a routine basis in the context of different real-world projects concerning estuarine flow and transport processes. Meanwhile the code of [[Trim|TRIM]]-3D has been optimized to improve performance on multiprocessor vector computers.


There exists a up to now no Standard Validation Document for TRIM-3D which would provide the potential user with information about the capabilities and limitations of the model.
There exists a up to now no Standard Validation Document for [[Trim|TRIM]]-3D which would provide the potential user with information about the capabilities and limitations of the [[model]].
==Preprocessors==
==Preprocessors==
* [[Generation of Boundary Conditions]]
* [[Generation of Boundary Conditions]]
* [[Generation and Modification of Computational Grids]]
* [[Generation and Modification of Computational Grids]]
==Programs for Simulation==
==Programs for Simulation==
* [[TR2VOR]]: generation of a compact version of the bathymetry-file together with some index arrays which are required during the simulation run for optimal performance on vector computers
* [[TR2VOR]]: generation of a compact version of the bathymetry-file together with some [[index]] arrays which are required during the simulation run for optimal performance on vector computers
* [[TR2LQ2]]: generation of a profile topography which is necessary to output results from a TRIM-3D simulation run along profiles
* [[TR2LQ2]]: generation of a profile topography which is necessary to output results from a [[Trim|TRIM]]-3D simulation run along profiles
* [[TRIM-3D]]: simulation run
* [[TRIM-3D]]: simulation run
==Postprocessors==
==Postprocessors==
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* [[VVIEW2D]]: graphical representation of CFD-data for vertical sections
* [[VVIEW2D]]: graphical representation of CFD-data for vertical sections
==General Data Flow==
==General Data Flow==
[http://www.baw.de/downloads/wasserbau/mathematische_verfahren/Modellverfahren/pdf/trim3d-de.pdf Graphical representation] of general flow of data related to a TRIM-3D application (with German text only). This graphical representation is also available in [http://www.baw.de/downloads/wasserbau/mathematische_verfahren/Modellverfahren/eps/trim3d-de1.eps Encapsulated PostScript Format].
[http://www.baw.de/downloads/wasserbau/mathematische_verfahren/Modellverfahren/pdf/trim3d-de.pdf Graphical representation] of general flow of data related to a [[Trim|TRIM]]-3D application (with German text only). This graphical representation is also available in [http://www.baw.de/downloads/wasserbau/mathematische_verfahren/Modellverfahren/eps/trim3d-de1.eps Encapsulated PostScript Format].
==Example Applications==
==Example Applications==
* [[Characteristic Numbers of Salinity (independent of tides)|tide independent characteristic numbers of salinity for a cross section in the Ems Estuary]].
* [[Characteristic Numbers of Salinity (independent of tides)|tide independent characteristic numbers of salinity for a cross section in the Ems Estuary]].
* [[propagation of short waves]] in a harbour basin (text available in German only)
* propagation of short waves in a [[harbour]] basin (text available in German only)
* [[Animations of salinity and flow velocity in the Außenems estuary]]
* Animations of salinity and flow velocity in the Außenems [[estuary]]
* [http://www.baw.de/downloads/wasserbau/mathematische_verfahren/Modellverfahren/pdf/trim3d-les.pdf A Second Order Lagrangian Method for Large Eddy Simulation]
* [http://www.baw.de/downloads/wasserbau/mathematische_verfahren/Modellverfahren/pdf/trim3d-les.pdf A Second Order Lagrangian Method for Large Eddy Simulation]
* [[secondary currents in river turns]], first results related to the project ''Minimierung der Unterhaltungsmaßnahmen im Bereich des Blexer Bogens'' (Lower Weser Estuary) --- available in German only
* secondary currents in river turns, first results related to the project ''Minimierung der Unterhaltungsmaßnahmen im Bereich des Blexer Bogens'' (Lower Weser [[Estuary]]) --- available in German only


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Latest revision as of 09:29, 21 October 2022

Short Description

The mathematical model TRIM-3D is based on the finite difference method. In contrast to the two-dimensional (depth-averaged) mathematical model TRIM-2D, TRIM-3D is a fully three-dimensional model. TRIM-3D was designed to solve several transient nonlinear partial differential equations (pde's). The model is actually used to study one ore more of the following physical processes:

  1. transport of water (conservation of the water mass)
  2. transport of linear momentum (conservation of linear momentum)
  3. transport of salinity (conservation of the dissolved salt mass)

The model takes into account hydrodynamic pressure in the water body (non-hydrostatic pressure distribution). A simplifying hydrostatic approximation can be alternatively used. This approximation might be useful for natural systems with negligible vertical accelerations (compared with gravity).

TRIM-3D was developed by Prof. V. Casulli (Trento University, Italy). In the framework of a scientific cooperation TRIM-3D has been successfully installed in the year 1996 at BAW-DHs computers. It has been integrated into BAW-DHs numerical modelling toolbox and is now used on a routine basis in the context of different real-world projects concerning estuarine flow and transport processes. Meanwhile the code of TRIM-3D has been optimized to improve performance on multiprocessor vector computers.

There exists a up to now no Standard Validation Document for TRIM-3D which would provide the potential user with information about the capabilities and limitations of the model.

Preprocessors

Programs for Simulation

  • TR2VOR: generation of a compact version of the bathymetry-file together with some index arrays which are required during the simulation run for optimal performance on vector computers
  • TR2LQ2: generation of a profile topography which is necessary to output results from a TRIM-3D simulation run along profiles
  • TRIM-3D: simulation run

Postprocessors

  • TR3MODATE: modification of date and time in a hydrodynamic results file if this hydrodynamic state should be used as initial state for a different date
  • TR3KACHEL: generation of sections (tiles); topography as well as data are cut into pieces out of the result files for the entire computational domain for any desired section (tile).
  • GVIEW2D: graphical display of time series at selected locations
  • LQ2PRO: Visualization of data along profiles
  • HVIEW2D: graphical display of 2D synoptic or data analyses results
  • VVIEW2D: graphical representation of CFD-data for vertical sections

General Data Flow

Graphical representation of general flow of data related to a TRIM-3D application (with German text only). This graphical representation is also available in Encapsulated PostScript Format.

Example Applications


back to Mathematical Models for Coastal Areas and Estuaries


Overview