Model:CBOFS2: Difference between revisions
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{{Model identity2 | {{Model identity2 | ||
|Categories=Marine | |Categories=Marine | ||
|One-line model description=Chesapeake Bay Operational Forecast System | |One-line model description=The Second Generation Chesapeake Bay Operational Forecast System (CBOFS2): A ROMS‐Based Modeling System | ||
|Extended model description=This is a special case of the Regional Ocean Modeling System(ROMS). Please see http://csdms.colorado.edu/wiki/Model:ROMS for details. | |Extended model description=This is a special case of the Regional Ocean Modeling System(ROMS). The National Ocean Service presently has an Operational Forecast System (CBOFS) for the Chesapeake Bay which generates only water levels and depth‐integrated currents. As a next generation system, a fully three‐dimensional, baroclinic Forecast System (CBOFS2) was developed, calibrated and validated; this system will produce water levels, currents, temperature and salinity. First, a two‐month tides only simulation was conducted to validate the water levels and currents and thereafter, a synoptic hindcast simulation from June 01, 2003–September 01, 2005 was conducted to validate water levels, currents, temperature and salinity. Upon comparison with observations, CBOFS2 for the most part met the target NOS water level error criteria and for current error, the criteria were met exceptionally well; the temperature and salinity errors were frequently less than 1 C and 3 PSU respectively. Hence, the predictive accuracy of CBOFS2 warranted it being accepted as a suitable three‐dimensional upgrade to CBOFS. | ||
Please see http://csdms.colorado.edu/wiki/Model:ROMS for details. | |||
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{{Start model keyword table}} | {{Start model keyword table}} | ||
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|Source web address=https://www.myroms.org/index.php?page=login | |Source web address=https://www.myroms.org/index.php?page=login | ||
|Program license type=Other | |Program license type=Other | ||
|Program license type other=MIT/X License, see License_ROMS.txt. | |Program license type other=MIT/X License, see License_ROMS.txt. | ||
|Memory requirements=Depends on application but it is relatively small in distributed-memory since only the tile partition is allocated for global and local arrays. All the state model variables are dynamically allocated and passed as arguments to the computational routines via de-referenced pointer structures. | |Memory requirements=Depends on application but it is relatively small in distributed-memory since only the tile partition is allocated for global and local arrays. All the state model variables are dynamically allocated and passed as arguments to the computational routines via de-referenced pointer structures. | ||
|Typical run time=Depends on application and resolution. Usually it takes several hours to run a realistic application for a simulation month. | |Typical run time=Depends on application and resolution. Usually it takes several hours to run a realistic application for a simulation month. | ||
}} | }} | ||
{{Input - Output description | {{Input - Output description | ||
|Describe input parameters=There are hundreds of input parameters for the physical, ecosystem, and sediment models. In addition, there are input scripts for floats, stations, model coupling, and data assimilation. | |Describe input parameters=There are hundreds of input parameters for the physical, ecosystem, and sediment models. In addition, there are input scripts for floats, stations, model coupling, and data assimilation. | ||
|Input format=ASCII | |Input format=ASCII | ||
|Other input format= ASCII (input scripts), NetCDF (input fields). | |Other input format=ASCII (input scripts), NetCDF (input fields). | ||
|Describe output parameters=There are hundreds of output parameters and fields that are written to several NetCDF files. | |Describe output parameters=There are hundreds of output parameters and fields that are written to several NetCDF files. | ||
|Other output format=NetCDF, CF-convections. | |Other output format=NetCDF, CF-convections. | ||
|Pre-processing software needed?=No | |Pre-processing software needed?=No | ||
|Post-processing software needed?=Yes | |Post-processing software needed?=Yes | ||
|Describe post-processing software=Yes, ROMS I/O is via NetCDF and follows CF-standard conventions. Therefore, any visualization software for NetCDF files can be used for pre- and post-processing. | |Describe post-processing software=Yes, ROMS I/O is via NetCDF and follows CF-standard conventions. Therefore, any visualization software for NetCDF files can be used for pre- and post-processing. | ||
|Visualization software needed?=Yes | |Visualization software needed?=Yes | ||
|Other visualization software=Yes, a plotting package is provided. It uses the NCAR's graphics Library. Any visualization package for NetCDF files can be used, like IDL, Matlab, and others. | |Other visualization software=Yes, a plotting package is provided. It uses the NCAR's graphics Library. Any visualization package for NetCDF files can be used, like IDL, Matlab, and others. | ||
}} | }} | ||
{{Process description model | {{Process description model | ||
|Describe processes represented by the model=ROMS resolved fast (gravity waves) and slow (Rossby waves) dynamics. Hydrostatic approximation but there is a nonhydrostatic version of ROMS. | |Describe processes represented by the model=ROMS resolved fast (gravity waves) and slow (Rossby waves) dynamics. Hydrostatic approximation but there is a nonhydrostatic version of ROMS. | ||
|Describe key physical parameters and equations=Navier-Stokes primitive equations. Bio-optical, biogeochemical, and ecosystem models equations. Cohesive and non cohesive sediment equations. Several vertical turbulece equations (KPP, GLS, MY-2.5). Air-Sea interaction coupling equations (COARE). Bottom boundary layer model equations. | |Describe key physical parameters and equations=Navier-Stokes primitive equations. Bio-optical, biogeochemical, and ecosystem models equations. Cohesive and non cohesive sediment equations. Several vertical turbulece equations (KPP, GLS, MY-2.5). Air-Sea interaction coupling equations (COARE). Bottom boundary layer model equations. | ||
|Describe length scale and resolution constraints=Estuary, regional, and basin scales. There are couple of global applications. | |Describe length scale and resolution constraints=Estuary, regional, and basin scales. There are couple of global applications. | ||
|Describe time scale and resolution constraints=Hours, days, seasons. It also can be used for climate research (decades). | |Describe time scale and resolution constraints=Hours, days, seasons. It also can be used for climate research (decades). | ||
|Describe any numerical limitations and issues=ROMS has a predictior-corrector algorithm that is efficient and accuarate. This class of model (terrain-following) exhibits stronger sensitivity to topography which results in pressure gradient errors. ROMS has several pressure gradient algorithms that minimize this problem. | |Describe any numerical limitations and issues=ROMS has a predictior-corrector algorithm that is efficient and accuarate. This class of model (terrain-following) exhibits stronger sensitivity to topography which results in pressure gradient errors. ROMS has several pressure gradient algorithms that minimize this problem. | ||
}} | }} | ||
{{Model testing | {{Model testing | ||
|Describe available calibration data sets=There are several idealized and realistic test cases. Some of the idealized test cases have quasi-analytical solutions. | |Describe available calibration data sets=There are several idealized and realistic test cases. Some of the idealized test cases have quasi-analytical solutions. | ||
|Describe available test data sets=We have a website for test problems: http://marine.rutgers.edu/po/index.php?model=test-problems | |Describe available test data sets=We have a website for test problems: http://marine.rutgers.edu/po/index.php?model=test-problems | ||
|Describe ideal data for testing=We have test cases for both laboratory and field observations. In the past, we have used data from rotating tanks. | |Describe ideal data for testing=We have test cases for both laboratory and field observations. In the past, we have used data from rotating tanks. | ||
}} | }} | ||
{{Users groups model | {{Users groups model | ||
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Warner, J. C., Sherwood, C. R., Signell, R. P., Harris, C. K., Arango, H. G., 2008. Development of a three-dimensional, regional, coupled wave, current, and sediment-transport model. Computer & Geosciences, 34, 1284~1306, Doi: (10.1016/j.cageo.2008.02.012). | Warner, J. C., Sherwood, C. R., Signell, R. P., Harris, C. K., Arango, H. G., 2008. Development of a three-dimensional, regional, coupled wave, current, and sediment-transport model. Computer & Geosciences, 34, 1284~1306, Doi: (10.1016/j.cageo.2008.02.012). | ||
Other papers are on the website: http://www.myroms.org/index.php?page=papers | Other papers are on the website: http://www.myroms.org/index.php?page=papers | ||
|Manual model available=Yes | |Manual model available=Yes | ||
|Model website if any=https://www.myroms.org | |Model website if any=https://www.myroms.org | ||
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There is a very active ROMS user's forum: https://www.myroms.org/forum | There is a very active ROMS user's forum: https://www.myroms.org/forum | ||
NOTICE: REGISTRATION IS NEEDED TO RECEIVE THE SOURCE CODE: https://www.myroms.org/index.php?page=login | NOTICE: REGISTRATION IS NEEDED TO RECEIVE THE SOURCE CODE: https://www.myroms.org/index.php?page=login | ||
}} | }} | ||
{{CSDMS staff part | {{CSDMS staff part |
Revision as of 14:42, 27 July 2011
CBOFS2
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