Property:Additional comments model

About this component: *This component was developed as part of the TopoFlow hydrologic model, which was originally written in IDL and had a point-and-click GUI. For more information on TopoFlow, please goto: https://csdms.colorado.edu/wiki/Model:TopoFlow. *When used from within the CSDMS Modeling Tool (CMT), this component has "config" button which launches a graphical user interface (GUI) for changing input parameters. The GUI is a tabbed dialog with a Help button at the bottom that displays HTML help in a browser window. *This component also has a configuration (CFG) file, with a name of the form: <case_prefix>_channels_diff_wave.cfg. This file can be edited with a text editor. *The Numerical Python module (numpy) is used for fast, array-based processing. *This model has an OpenMI-style interface, similar to OpenMI 2.0. Part of this interface is inherited from "CSDMS_base.py".  +

About this component: *This component was developed as part of the TopoFlow hydrologic model, which was originally written in IDL and had a point-and-click GUI. For more information on TopoFlow, please goto: https://csdms.colorado.edu/wiki/Model:TopoFlow. *When used from within the CSDMS Modeling Tool (CMT), this component has "config" button which launches a graphical user interface (GUI) for changing input parameters. The GUI is a tabbed dialog with a Help button at the bottom that displays HTML help in a browser window. *This component also has a configuration (CFG) file, with a name of the form: <case_prefix>_channels_diff_wave.cfg. This file can be edited with a text editor. *The Numerical Python module (numpy) is used for fast, array-based processing. *This model has an OpenMI-style interface, similar to OpenMI 2.0. Part of this interface is inherited from "CSDMS_base.py".  +

About this component: *This component was developed as part of the TopoFlow hydrologic model, which was originally written in IDL and had a point-and-click GUI. For more information on TopoFlow, please goto: https://csdms.colorado.edu/wiki/Model:TopoFlow. *When used from within the CSDMS Modeling Tool (CMT), this component has "config" button which launches a graphical user interface (GUI) for changing input parameters. The GUI is a tabbed dialog with a Help button at the bottom that displays HTML help in a browser window. *This component also has a configuration (CFG) file, with a name of the form: <case_prefix>_channels_diff_wave.cfg. This file can be edited with a text editor. *The Numerical Python module (numpy) is used for fast, array-based processing. *This model has an OpenMI-style interface, similar to OpenMI 2.0. Part of this interface is inherited from "CSDMS_base.py".  +

About this component: *This component was developed as part of the TopoFlow hydrologic model, which was originally written in IDL and had a point-and-click GUI. For more information on TopoFlow, please goto: https://csdms.colorado.edu/wiki/Model:TopoFlow. *When used from within the CSDMS Modeling Tool (CMT), this component has "config" button which launches a graphical user interface (GUI) for changing input parameters. The GUI is a tabbed dialog with a Help button at the bottom that displays HTML help in a browser window. *This component also has a configuration (CFG) file, with a name of the form: <case_prefix>_channels_diff_wave.cfg. This file can be edited with a text editor. *The Numerical Python module (numpy) is used for fast, array-based processing. *This model has an OpenMI-style interface, similar to OpenMI 2.0. Part of this interface is inherited from "CSDMS_base.py".  +

About this component: *This component was developed as part of the TopoFlow hydrologic model, which was originally written in IDL and had a point-and-click GUI. For more information on TopoFlow, please goto: https://csdms.colorado.edu/wiki/Model:TopoFlow. *When used from within the CSDMS Modeling Tool (CMT), this component has "config" button which launches a graphical user interface (GUI) for changing input parameters. The GUI is a tabbed dialog with a Help button at the bottom that displays HTML help in a browser window. *This component also has a configuration (CFG) file, with a name of the form: <case_prefix>_channels_diff_wave.cfg. This file can be edited with a text editor. *The Numerical Python module (numpy) is used for fast, array-based processing. *This model has an OpenMI-style interface, similar to OpenMI 2.0. Part of this interface is inherited from "CSDMS_base.py".  +

About this component: *This component was developed as part of the TopoFlow hydrologic model, which was originally written in IDL and had a point-and-click GUI. For more information on TopoFlow, please goto: https://csdms.colorado.edu/wiki/Model:TopoFlow. *When used from within the CSDMS Modeling Tool (CMT), this component has "config" button which launches a graphical user interface (GUI) for changing input parameters. The GUI is a tabbed dialog with a Help button at the bottom that displays HTML help in a browser window. *This component also has a configuration (CFG) file, with a name of the form: <case_prefix>_channels_diff_wave.cfg. This file can be edited with a text editor. *The Numerical Python module (numpy) is used for fast, array-based processing. *This model has an OpenMI-style interface, similar to OpenMI 2.0. Part of this interface is inherited from "CSDMS_base.py".  +

About this component: *This component was developed as part of the TopoFlow hydrologic model, which was originally written in IDL and had a point-and-click GUI. For more information on TopoFlow, please goto: https://csdms.colorado.edu/wiki/Model:TopoFlow. *When used from within the CSDMS Modeling Tool (CMT), this component has "config" button which launches a graphical user interface (GUI) for changing input parameters. The GUI is a tabbed dialog with a Help button at the bottom that displays HTML help in a browser window. *This component also has a configuration (CFG) file, with a name of the form: <case_prefix>_channels_diff_wave.cfg. This file can be edited with a text editor. *The Numerical Python module (numpy) is used for fast, array-based processing. *This model has an OpenMI-style interface, similar to OpenMI 2.0. Part of this interface is inherited from "CSDMS_base.py".  +

About this component: *This component was developed as part of the TopoFlow hydrologic model, which was originally written in IDL and had a point-and-click GUI. For more information on TopoFlow, please goto: https://csdms.colorado.edu/wiki/Model:TopoFlow. *When used from within the CSDMS Modeling Tool (CMT), this component has "config" button which launches a graphical user interface (GUI) for changing input parameters. The GUI is a tabbed dialog with a Help button at the bottom that displays HTML help in a browser window. *This component also has a configuration (CFG) file, with a name of the form: <case_prefix>_channels_diff_wave.cfg. This file can be edited with a text editor. *The Numerical Python module (numpy) is used for fast, array-based processing. *This model has an OpenMI-style interface, similar to OpenMI 2.0. Part of this interface is inherited from "CSDMS_base.py".  +

Active development and maintenance of the code has moved to GitHub and been incorporated within broader LSDTopoTools software package: https://github.com/LSDtopotools/LSDTopoTools2  +

All links to documentation of WOFOST are available on the WOFOST page on the WageningenUR web site given above.  +

All the model information can be found in: https://sites.google.com/view/olaflowcfd/home  +

Associated paper: Salles et al., (2020). gospl: Global Scalable Paleo Landscape Evolution. Journal of Open Source Software, 5(56), 2804, https://doi.org/10.21105/joss.02804  +

Barely started; using this as a testbed for the new CSDMS BMI interface.  +

Barnhart, K. R., Glade, R. C., Shobe, C. M., and Tucker, G. E.: Terrainbento 1.0: a Python package for multi-model analysis in long-term drainage basin evolution, Geosci. Model Dev., 12, 1267-1297, https://doi.org/10.5194/gmd-12-1267-2019, 2019.  +

Both codes are undergoing extensive revisions needed to incorporate them into the framework of the NearCoM Nearshore Community Model.  +

Code is research grade.  +

Current version is 5.0  +

Disclaimer Although every effort is made to provide timely and accurate information, the authors, the U.S. Geological Survey (USGS), and the U.S. Government make no warranty, expressed or implied, as to the timeliness or accuracy of the contents of this web site, which may be updated and revised at any time. Any use of trade, product, or firm names in this publication is for descriptive purposes only and does not imply endorsement by the U.S. Government. Any links to non-Government web sites are provided for convenience only and do not imply endorsement by the U.S. Government.  +

Documentation available at: https://github.com/UNC-CECL/BarrierBMFT  +

Email to Chris.jenkins@colorado.edu for further details, manual, code, collaboration  +

FVCOM is an open source code ocean community model that always welcomes new users. This program is only permitted for use in non-commercial academic research and education. Users are required to register in orde to receive the source codes, demo examples, and user manuals as well as some recommended postprocessing tools.  +

For details on the methodology and underlying benchmarking philosophy, see the following paper: Nathan Collier, Forrest M. Hoffman, David M. Lawrence, Gretchen Keppel‐Aleks, Charles D. Koven, William J. Riley, Mingquan Mu, and James T. Randerson, "The International Land Model Benchmarking (ILAMB) System: Design, Theory, and Implementation", JAMES, 10 (11), 2018, https://doi.org/10.1029/2018MS001354  +

Form filled out by Albert Kettner from information available on the web.  +

Form was filled out by Albert Kettner, based on information available on the web  +

GOLEM was written in the 1990s by one of the creators of CHILD. Although it lacks many of the special capabilities of CHILD, it has a simpler, more compact code base (just a single C source file) and uses a raster grid data structure.  +

I currently have an NSF-CMG grant to work with Greg Tucker, Tom Manteuffel and Steve McCormick to find faster algorithms for this type of model.  +

Information provided by Bert Jagers  +

Laura Moore updated this questionaire and uploaded sample simulations and a user's guide on 10/29/2012.  +

Limitations of FACET. The accuracy of FACET output depends on the quality and resolution of the DEM used. The user should not interpret FACET stream and floodplain geomorphic measurements as a replacement for on-the-ground measurements of geomorphic characteristic. Rather, FACET provides a tool to rapidly assess patterns in geomorphic characteristics at a regional scale. Any FACET output should be screened for outliers and abnormalities.  +

Linkages Supported: Links to GLUE (Generalized Likelihood Uncertainty Estimation) program for sensitivity/uncertainty/calibration analyses.  +

Manual/videos/walkthroughs available through the wiki on the sourceforge site above.  +

Mariotti, G., AC Spivak, SY Luk, G Ceccherini, M Tyrrell, ME Gonneea, (2020), Modeling the spatial dynamics of marsh ponds in New England salt marshes, Geomorphology, 107262 https://www.sciencedirect.com/science/article/abs/pii/S0169555X20302348  +

Mariotti, G., W.S. Kearney, S. Fagherazzi, (2016), Soil creep in salt marshes, Geology, 44 (6), 459-462.  +

Method is also available as part of the Freeware SedLog package - see http://www.sedlog.com/  +

Model described in: G. Mariotti, and J. Carr, (2014), Dual role of salt marsh retreat: Long-term loss and short-term resilience, WRR, DOI: 10.1002/2013WR014676. The source code reproduce figure 2 of this paper.  +

Model description and calibration can be found in: Leonardi, N., and S. Fagherazzi (2014), How waves shape salt marshes, Geology , doi:10.1130/G35751.1. Leonardi, N., and S. Fagherazzi (2015), Local variability in erosional resistance affects large scale morphodynamic response of salt marshes to wind waves, Geophysical Research Letters, 2015GL064730, doi:10.1002/2015GL064730.  +

Model questionnaire filled out based on website, by Albert Kettner  +

Model requires the use of the FFTW discrete Fourier transform subroutine library. Users should independently download this library, which is available at: http://www.fftw.org  +

Model was initially developed to interpolate between analogue experiments and landscape evolution done at the Utrecht University by George Postma and coworkers.  +

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