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conversion of Delft3D computational results
conversion of Delft3D computational results
|shortdescription=
|shortdescription=
Program DATACONVERT is used to convert computational results from the integrated modelling system Delft3D into BAW-specific data formats. The following conversions are currently supported:
Program DATACONVERT is used to convert computational results from the integrated modelling system Delft3D into BAW-specific data formats. The following conversions are currently supported:<br />


    * conversion of a Delft3D computational grid into UnTRIM grid format,
* conversion of a Delft3D computational grid into UnTRIM grid format,
    * conversion of two-dimensional (depth averaged) Delft3D computational results into BDF data format (2D),
* conversion of two-dimensional (depth averaged) Delft3D computational results into BDF data format (2D),
    * conversion and depth averaging of three-dimensional Delft3D computational results into BDF data format (2D), and
* conversion and depth averaging of three-dimensional Delft3D computational results into BDF data format (2D), and
    * conversion of three-dimensional Delft3D computational results (sigma-coordinates) into BDF data format (3D, z-layers).
* conversion of three-dimensional Delft3D computational results (sigma-coordinates) into BDF data format (3D, z-layers).<br />


Dynamic model bathymetry (morphodynamics) is supported for 2D as well as 3D computational results. If Delft3D model results have been produced for a domain decomposition run, the converted results are written to different domain-specific data files and are not yet combined into one single file.<br />
Dynamic model bathymetry (morphodynamics) is supported for 2D as well as 3D computational results. If Delft3D model results have been produced for a domain decomposition run, the converted results are written to different domain-specific data files and are not yet combined into one single file.<br />
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# vertical erosion.<br />  
# vertical erosion.<br />  


Input-Files:
|inputfiles=
 
# '''steering data'''
  1. steering data
:file of type [[DATACONVERT.DAT|dataconvert.dat]]. The extended description for this file contains comprehensive informations with respect to steering data, input as well as output data files.
      file of type dataconvert.dat. The extended description for this file contains comprehensive informations with respect to steering data, input as well as output data files.
# '''computational grid'''
  2. computational grid
::required:
      required:
::* [[DELFT3D.GRD|delft3d.grd]],
          * delft3d.grd,
::* [[DELFT3D.DEP|delft3d.dep]], and
          * delft3d.dep, and
::* [[DELFT3D.ENC|delft3d.enc]].<br />
          * delft3d.enc.
:: optional:
      optional:
::* [[DELFT3D.DRY|delft3d.dry]],
          * delft3d.dry,
::* [[DELFT3D.THD|delft3d.thd]],
          * delft3d.thd,
::* [[DELFT3D.LWL|delft3d.lwl]],
          * delft3d.lwl,
::* [[DELFT3D.EXT|delft3d.ext]], as well as
          * delft3d.ext, as well as
::* [[DELFT3D.BND|delft3d.bnd]].<br />
          * delft3d.bnd.


# computational results
# computational results


    * netcdf.cdf.
:* [[NETCDF.CDF|netcdf.cdf]].


# (optional) vertical structure
# (optional) vertical structure


    * vertical.dat.
:* [[VERTICAL.DAT|vertical.dat]].<br />
 
Output-Files:


  1. converted computational grid
|outputfiles=
          * untrim_grid.dat.
  2. converted computational results
          * dirz.bin.R,
          * dirz.bin.I, and
          * dirz.bin.
  3. printer file
          * dataconvert.sdr.
  4. (optional) trace file
          * dataconvert.trc.


# '''converted computational grid'''
::* [[UNTRIM_GRID.DAT|untrim_grid.dat]].
# '''converted computational results'''
::* [[DIRZ.BIN.I|dirz.bin.R]],
::* [[DIRZ.BIN.I|dirz.bin.I]], and
::* [[DIRZ.BIN|dirz.bin]].
# '''printer file'''
::* dataconvert.sdr.
# (optional) '''trace file'''
::* dataconvert.trc.


|methodology=The original computational grid is converted using methods from software package H_GRID. Conversion of computational results is performed using methods from the H_IP package. Read and Write of computational data is carried through using several methods from software package IO_DATASET.   
|methodology=The original computational grid is converted using methods from software package H_GRID. Conversion of computational results is performed using methods from the H_IP package. Read and Write of computational data is carried through using several methods from software package IO_DATASET.   
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|contact_original=[mailto:mailto:günter.lang@baw.de G. Lang]
|contact_original=[mailto:mailto:günter.lang@baw.de G. Lang]
|contact_maintenance=[mailto:mailto:günter.lang@baw.de G. Lang,], [mailto:susanne.spohr@baw.de S. Spohr,]
|contact_maintenance=[mailto:mailto:günter.lang@baw.de G. Lang,], [mailto:susanne.spohr@baw.de S. Spohr,]
|documentation=$PROGHOME/examples/dataconvert  
|documentation=for example input files please refer to $PROGHOME/examples/dataconvert  
}}
}}

Revision as of 09:14, 4 May 2010

Basic Information

Name of Program

DATACONVERT

Version-Date

6.x / October 2007

Description-Date

October 2007

Catchwords

conversion of Delft3D computational grid
conversion of Delft3D computational results

Short Description of Functionality

Program DATACONVERT is used to convert computational results from the integrated modelling system Delft3D into BAW-specific data formats. The following conversions are currently supported:

  • conversion of a Delft3D computational grid into UnTRIM grid format,
  • conversion of two-dimensional (depth averaged) Delft3D computational results into BDF data format (2D),
  • conversion and depth averaging of three-dimensional Delft3D computational results into BDF data format (2D), and
  • conversion of three-dimensional Delft3D computational results (sigma-coordinates) into BDF data format (3D, z-layers).

Dynamic model bathymetry (morphodynamics) is supported for 2D as well as 3D computational results. If Delft3D model results have been produced for a domain decomposition run, the converted results are written to different domain-specific data files and are not yet combined into one single file.

Conversion of subsequent physical quantities is currently possible:

  1. water level,
  2. current velocity,
  3. salinity,
  4. temperature,
  5. suspended sediment (several fractions),
  6. bathymetry (static),
  7. transient bathymetric depth, and
  8. vertical erosion.

Input-Files

  1. steering data
file of type dataconvert.dat. The extended description for this file contains comprehensive informations with respect to steering data, input as well as output data files.
  1. computational grid
required:
optional:
  1. computational results
  1. (optional) vertical structure

Output-Files

  1. converted computational grid
  1. converted computational results
  1. printer file
  • dataconvert.sdr.
  1. (optional) trace file
  • dataconvert.trc.

Methodology

The original computational grid is converted using methods from software package H_GRID. Conversion of computational results is performed using methods from the H_IP package. Read and Write of computational data is carried through using several methods from software package IO_DATASET.

Program(s) to run before this Program

DELFT3D, GETDATA

Program(s) to run after this Program

ABDF, ADCP2PROFILE, DIDAMERGE, DIDARENAME, DIDASPLIT, ENERF, GVIEW2D, HVIEW2D, IO_VOLUME, PARTRACE, PARTRACE-3D, PGCALC, UNK, UNS, VTDK, XTRDATA, XTRLQ2, ZEITR.

Additional Information

Language

FORTRAN 90

Additional software

-

Original Version

G. Lang

Maintenance

G. Lang,, S. Spohr,

Documentation/Literature

for example input files please refer to $PROGHOME/examples/dataconvert


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