Model:Gvg3Dp: Difference between revisions

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{{Infobox Model
{{Model identity
|model name              = Gvg3Dp
|Model type=Single
|developer                = '''Nasr Azadani''', Mohamad Mehdi
|one-line-description    = 3D Numerical Simulation of Turbidity Currents
|type                     = Model
|source                  = [[image:Red1.png]]
}}
}}
<!-- Edit the part above to update info on other papers -->
{{Model identity2
 
|ModelDomain=Marine
== Gvg3Dp ==
|Spatial dimensions=3D
__TOC__
|One-line model description=3D Numerical Simulation of Turbidity Currents
 
|Extended model description=Three dimensional simulations of the Turbidity currents using DNS of incompressible Navier-Stokes and transport equations.
===Introduction===
}}
 
{{Start model keyword table}}
=== History ===
{{Model keywords
 
|Model keywords=turbidity current
=== Papers ===
}}
 
{{Model keywords
=== Gvg3Dp Questionnaire ===
|Model keywords=flow dynamics
 
}}
==== Contact Information ====
{{End a table}}
 
{{Modeler information
{| class="wikitable"
|First name=Mohamad Mehdi
| class="model_col1"| Model:
|Last name=Nasr Azadani
| class="model_col2"| Gvg3Dp
|Type of contact=Model developer
|-
|Institute / Organization=University of California, Santa Barbara
| class="model_col1"| Contact person:
|Postal address 1=Engr II Bldg, Room 2301
| class="model_col2"| Mohamad Mehdi Nasr Azadani (Model developer)
|Postal address 2=Mechanical Engineering Department, UC Santa Barbara
|-
|Town / City=Santa Barabra
| class="model_col1"| Institute:
|Postal code=93106
| class="model_col2"| University of California, Santa Barbara  
|State=California
|-
|Country=United States
| class="model_col1"| City:
|Email address=mmnasr@engr.ucsb.edu
| class="model_col2"| Santa Barbara, CA
|Phone=805-893-6107
|-
}}
| class="model_col1"| Country:
{{Model technical information
| class="model_col2"| USA
|Supported platforms=Unix, Linux
|-
|Programming language=C
| class="model_col1"| Email:
|Start year development=2006
| class="model_col2"| mmnasr@engr.ucsb.edu
|Does model development still take place?=Yes
|-
|Model availability=As code
| class="model_col1"| 2nd person involved:
|Program license type=GPL v2
| class="model_col2"| --
|Memory requirements=Typical ratio: 250,000 nodes requires 1 Gbyte
|-
|Typical run time=--
| class="model_col1"| 3rd person involved:
}}
| class="model_col2"| --
{{Input - Output description
|}
|Describe input parameters=Input parameters:
 
==== Model description ====
 
{| class="wikitable"
| class="model_col1"| Model type:
| class="model_col2"| Single model
|-
| class="model_col1"| Description:
| class="model_col2"| Three dimensional simulations of the Turbidity currents using DNS of incompressible Navier-Stokes and transport equations.
|}
 
==== Technical information ====
 
{| class="wikitable"
| class="model_col1"| Supported platforms:
| class="model_col2"| UNIX, Linux
|-
| class="model_col1"| Programming language:
| class="model_col2"| C
|-
| class="model_col1"| Model was developed started from:
| class="model_col2"| 2006 and development still takes place
|-
| class="model_col1"| To what degree will the model become available:
| class="model_col2"| As code
|-
| class="model_col1"| Current license type:
| class="model_col2"| GPLv2
|-
| class="model_col1"| Memory requirements:
| class="model_col2"| Typical ratio: 250,000 nodes requires 1 Gbyte
|-
| class="model_col1"| Typical run time:
| class="model_col2"| --
|}
 
==== Input / Output description ====
 
{| class="wikitable"
| class="model_col1"| Input parameters:
| class="model_col2"|
*Geometrical parameters: Nx, Ny, Nz.
*Geometrical parameters: Nx, Ny, Nz.
*Grid: Uniform or nonuniform.
*Grid: Uniform or nonuniform.
Line 92: Line 47:
*Particle Parameters: Settling velocities.
*Particle Parameters: Settling velocities.
*Flags: Output writing flags. Inflow/Outflow to the domain flags.
*Flags: Output writing flags. Inflow/Outflow to the domain flags.
 
|Input format=ASCII
 
|Describe output parameters=Depending on the flags indicated in the input file, typical flow quantities are stored to the file at the given time steps.<br>
 
|-
| class="model_col1"| Input format:
| class="model_col2"| ASCII
|-
| class="model_col1"| Output parameters:
| class="model_col2"| Depending on the flags indicated in the input file, typical flow quantities are stored to the file at the given time steps.<br>
Velocities, Pressure, Concentration (of the particles).<br>
Velocities, Pressure, Concentration (of the particles).<br>
Depending on the problems, some other quantities could be stored too.  
Depending on the problems, some other quantities could be stored too.
|-
|Output format=ASCII, Binary
| class="model_col1"| Output format:
|Pre-processing software needed?=No
| class="model_col2"| ASCII, Binary
|Post-processing software needed?=Yes
|-
|Describe post-processing software=Yes, a C code is developed for this gvg3Dp in order to convert the raw binary data into the xml-vtr format which can be read using paraview software.
| class="model_col1"| Post-processing software (if needed):
|Visualization software needed?=Yes
| class="model_col2"| Yes, a C code is developed for this gvg3Dp in order to convert the raw binary data into the xml-vtr format which can be read using paraview software.
|Other visualization software=Paraview
|-
}}
| class="model_col1"| Visualization software (if needed):
{{Process description model
| class="model_col2"| Yes, Paraview
|Describe processes represented by the model=Any type of turbidity (or gravity) currents could be modeled with this code. Is also handles the flows passing complex topographies, inflow/outflows too.
|}
|Describe key physical parameters and equations=Incompressible flow equations: Navier-Stokes with Boussinesq approximations. Transport equation to describe the motion of particles (or Salanity or Temperature).
|Describe length scale and resolution constraints=With the current version of the code (DNS and no turbulence model) we are restricted to low Reynolds numbers. Up to maximum 10,000.
|Describe time scale and resolution constraints=--
|Describe any numerical limitations and issues=--
}}
{{Model testing
|Describe available calibration data sets=
|Describe available test data sets=
|Describe ideal data for testing=
}}
{{Users groups model
|Do you have current or future plans for collaborating with other researchers?=--
}}
{{Documentation model
|Provide key papers on model if any=Key Papers:
* '''F.Necker, C.Hartel, L.Kleiser,E.Meiburg, 2002. High-resolution simulations of particle-driven gravity currents. International Journal of Multiphase FLow, 28:279~300. Doi: ([http://dx.doi.org/10.1016/S0301-9322(01)00065-9 10.1016/S0301-9322(01)00065-9]).'''
|Manual model available=No
}}
{{Additional comments model}}
{{CSDMS staff part
|OpenMI compliant=No but possible
|CCA component=No but possible
|IRF interface=No but possible
|CMT component=No but possible
}}
{{Start coupled table}}
{{End a table}}
{{End headertab}}
{{{{PAGENAME}}_autokeywords}}


==== Process description ====
{{NOINDEX}}
 
<!-- Edit the part above to update info on other papers -->
{| class="wikitable"
| class="model_col1"| Processes represented by model:
| class="model_col2"| Any type of turbidity (or gravity) currents could be modeled with this code. Is also handles the flows passing complex topographies, inflow/outflows too.
|-
| class="model_col1"| Key physical parameters & equations:
| class="model_col2"| Incompressible flow equations: Navier-Stokes with Boussinesq approximations. Transport equation to describe the motion of particles (or Salanity or Temperature).
|-
| class="model_col1"| Length scale & resolution constraints:
| class="model_col2"| With the current version of the code (DNS and no turbulence model) we are restricted to low Reynolds numbers. Up to maximum 10,000.
|-
| class="model_col1"| Time scale & resolution constraints:
| class="model_col2"| --
|-
| class="model_col1"| Numerical limitations and issues :
| class="model_col2"| --
|}
 
==== Testing ====
 
{| class="wikitable"
| class="model_col1"| Available calibration data sets:
| class="model_col2"| --
|-
| class="model_col1"| Available test data sets:
| class="model_col2"| --
|-
| class="model_col1"| Ideal data for testing:
| class="model_col2"| --
|}
 
==== User groups ====
 
{| class="wikitable"
| class="model_col1"| Currently or plans for collaborating with:
| class="model_col2"| --
|}
 
==== Documentation ====
 
{| class="wikitable"
| class="model_col1"| Key papers of the model:
| class="model_col2"| High Resolution Simulations of Particle-Driven Gravity Currents,  with V. Birman, F. Blanchette, M. Strauss, B. Kneller, M.E. Glinsky, F. Necker, C. Härtel and L. Kleiser. Direct and Large Eddy Simulation VI (Springer), Poitiers, France, September 2005
|-
| class="model_col1"| Is there a manual available:
| class="model_col2"| No
|-
| class="model_col1"| Model website if any:
| class="model_col2"| --
|}
 
==== Additional comments ====


{| class="wikitable"
==Introduction==
| class="model_col1"| Comments:
| class="model_col2"| --
|}


=== Issues ===
== History ==


=== Help ===
== References  ==
<br>{{AddReferenceUploadButtons}}<br><br>
{{#ifexist:Template:{{PAGENAME}}-citation-indices|{{{{PAGENAME}}-citation-indices}}|}}<br>
{{Include_featured_references_models_cargo}}<br>


=== Input Files ===
== Issues ==


=== Output Files ===
== Help ==
{{#ifexist:Model_help:{{PAGENAME}}|[[Model_help:{{PAGENAME}}]]|}}


=== Download ===
== Input Files ==


=== Source ===
== Output Files ==


[[Category:Marine]]
[[Category:Source code not available]]

Latest revision as of 20:17, 16 September 2020



Gvg3Dp


Metadata

Also known as
Model type Single
Model part of larger framework
Note on status model
Date note status model
Spatial dimensions 3D
Spatial extent
Model domain Marine
One-line model description 3D Numerical Simulation of Turbidity Currents
Extended model description Three dimensional simulations of the Turbidity currents using DNS of incompressible Navier-Stokes and transport equations.
Keywords:

turbidity current, flow dynamics,

Name Mohamad Mehdi Nasr Azadani
Type of contact Model developer
Institute / Organization University of California, Santa Barbara
Postal address 1 Engr II Bldg, Room 2301
Postal address 2 Mechanical Engineering Department, UC Santa Barbara
Town / City Santa Barabra
Postal code 93106
State California
Country United States
Email address mmnasr@engr.ucsb.edu
Phone 805-893-6107
Fax


Supported platforms
Unix, Linux
Other platform
Programming language

C

Other program language
Code optimized
Multiple processors implemented
Nr of distributed processors
Nr of shared processors
Start year development 2006
Does model development still take place? Yes
If above answer is no, provide end year model development
Code development status
When did you indicate the 'code development status'?
Model availability As code
Source code availability
(Or provide future intension)
Source web address
Source csdms web address
Program license type GPL v2
Program license type other
Memory requirements Typical ratio: 250,000 nodes requires 1 Gbyte
Typical run time --


Describe input parameters Input parameters:
  • Geometrical parameters: Nx, Ny, Nz.
  • Grid: Uniform or nonuniform.
  • Flow Parameters: Reynolds, Peclet
  • Particle Parameters: Settling velocities.
  • Flags: Output writing flags. Inflow/Outflow to the domain flags.
Input format ASCII
Other input format
Describe output parameters Depending on the flags indicated in the input file, typical flow quantities are stored to the file at the given time steps.

Velocities, Pressure, Concentration (of the particles).
Depending on the problems, some other quantities could be stored too.

Output format ASCII, Binary
Other output format
Pre-processing software needed? No
Describe pre-processing software
Post-processing software needed? Yes
Describe post-processing software Yes, a C code is developed for this gvg3Dp in order to convert the raw binary data into the xml-vtr format which can be read using paraview software.
Visualization software needed? Yes
If above answer is yes
Other visualization software Paraview


Describe processes represented by the model Any type of turbidity (or gravity) currents could be modeled with this code. Is also handles the flows passing complex topographies, inflow/outflows too.
Describe key physical parameters and equations Incompressible flow equations: Navier-Stokes with Boussinesq approximations. Transport equation to describe the motion of particles (or Salanity or Temperature).
Describe length scale and resolution constraints With the current version of the code (DNS and no turbulence model) we are restricted to low Reynolds numbers. Up to maximum 10,000.
Describe time scale and resolution constraints --
Describe any numerical limitations and issues --


Describe available calibration data sets
Upload calibration data sets if available:
Describe available test data sets
Upload test data sets if available:
Describe ideal data for testing


Do you have current or future plans for collaborating with other researchers? --
Is there a manual available? No
Upload manual if available:
Model website if any
Model forum / discussion board
Comments


This part will be filled out by CSDMS staff

OpenMI compliant No but possible
BMI compliant No but possible
WMT component No but possible
PyMT component
Is this a data component
Can be coupled with:
Model info
Authors
Mohamad Mehdi Nasr Azadani
Source code
Model citations
Nr. of publications: --
Total citations: 0
h-index: --"--" is not a number.
m-quotient: 0
QR-code

Link to this page
Other models by author

Template:Gvg3Dp autokeywords


Introduction

History

References



Nr. of publications: --
Total citations: 0
h-index: --"--" is not a number.
m-quotient: 0


See more publications of Gvg3Dp

Issues

Help

Input Files

Output Files

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