SMS:River FLO: Difference between revisions
From XMS Wiki
Jump to navigationJump to search
(Blanked the page) |
No edit summary |
||
| Line 1: | Line 1: | ||
{{SMS Infobox Model | | |||
|name= SRH-2D | |||
|model_type= Two-dimensional (2D) hydraulic, sediment, temperature, and vegetation model for river systems | |||
|developer= | |||
Yong Lai <br /> | |||
Bureau of Reclamation | |||
|web_site= [http://www.usbr.gov/pmts/sediment/model/srh2d/index.html SRH-2D web site] | |||
|tutorials= | |||
General Section | |||
* Data Visualization | |||
* Mesh Editing | |||
* Observation | |||
Models Section | |||
* SRH-2D (Pending) | |||
}} | |||
== About SRH-2D == | |||
SRH-2D, Sedimentation and River Hydraulics – Two-Dimensional model, is a two-dimensional (2D) hydraulic, sediment, temperature, and vegetation model for river systems under development at the Bureau of Reclamation. Different versions of SRH-2D contain different modules, as listed below (only version 2 is released and the rest will be released in the future): | |||
* SRH-2D version 2: Modeling of flow hydraulics for stream/river systems | |||
* SRH-2D version 3: Mobile bed sediment transport module added to v.2 '''(Not yet released)''' | |||
* SRH-2D version 4: Temperature and vegetation module added to version v.2 '''(Not yet released)''' | |||
* For watershed runoff modeling, SRH-W v.1.1 should be used. | |||
== About SRH-2D Version 2 == | |||
SRH-2D version 2 solves the 2D dynamic wave equations, i.e., the depth-averaged St. Venant equations. Its modeling capability is comparable to some existing 2D models but SRH-2D claims a few boasting features. First, SRH-2D uses a flexible mesh that may contain arbitrarily shaped cells. In practice, the hybrid mesh of quadrilateral and triangular cells is recommended though purely quadrilateral or triangular elements may be used. A hybrid mesh may achieve the best compromise between solution accuracy and computing demand. Second, SRH-2D adopts very robust and stable numerical schemes with a seamless wetting-drying algorithm. The resultant outcome is that few tuning parameters are needed to obtain the final solution. SRH-2D was evolved from SRH-W which had the additional capability of watershed runoff modeling. Many features are improved from SRH-W. | |||
=== Major Features of SRH-2D v. 2 === | |||
Major SRH-2D capabilities are listed below | |||
* 2D depth-averaged dynamic wave equations (the standard St. Venant equations) are solved with the finite-volume numerical method | |||
* Steady state (with constant discharge) or unsteady flows (with flow hydrograph) may be simulated | |||
* An implicit scheme is used for time integration to achieve solution robustness and efficiency | |||
* An unstructured arbitrarily-shaped mesh is used which includes the structured quadrilateral mesh, the purely triangular mesh, or a combination of the two. Cartesian or raster mesh may also be used. In most applications, a combination of quadrilateral and triangular meshes is the best in terms of efficiency and accuracy | |||
* All flow regimes, i.e., subcritical, transcritical, and supercritical flows, may be simulated simultaneously without the need for special treatments | |||
* Robust and seamless wetting-drying algorithm; an | |||
* Solved variables include water surface elevation, water depth, and depth averaged velocity. Output variables include the above, plus Froude number, bed shear stress, critical sediment diameter, and sediment transport capacity. | |||
SRH-2D is a 2D model, and it is particularly useful for problems where 2D effects are important. Examples include flows with in-stream structures, through bends, with perched rivers, with side channel and agricultural returns, and with braided channel systems. A 2D model may also be needed if one is interested in local flow velocities, eddy patterns, flow recirculation, lateral velocity variation, and flow over banks and levees. | |||
== Features == | |||
* SRH-2D solves the 2D depth-averaged form of the diffusive wave or the dynamic wave equations. The dynamic wave equations are the standard St. Venant depth-averaged shallow water equations | |||
* Both the diffusive wave and dynamic wave solvers use the implicit scheme to achieve solution robustness and efficiency | |||
* Both steady or unsteady flows may be simulated | |||
* All flow regimes, i.e., subcritical, transcritical, and supercritical flows, may be simulated simultaneously without the need of a special treatment | |||
* Solution domain may include a combination of main channels, side channels, floodplains, and overland | |||
* Solved variables include water surface elevation, water depth, and depth averaged velocity. Output information includes above variables, plus flow inundation, Froude number, and bed shear stress | |||
SRH-2D is a 2D model and it is particularly useful for problems where 2D effects are important. Examples include flows with in-stream structures, through bends, with perched rivers, with multiple channel systems, and with complex floodplains. A 2D model may also be needed if one is interested in local flow velocities, eddy patterns and flow recirculation, lateral variations, flow spills over banks and levees, and flow diversion and bifurcation. | |||
'''The Bureau of Reclamation does not provide technical support for SRH-2D.''' | |||
==Graphical Interface== | |||
SRH-2D uses the [[SMS:Generic_Model_Graphical_Interface|Generic Model Graphical Interface]]. The [http://www.usbr.gov/pmts/sediment/model/srh2d/Downloads/SRH2D-v2-Distribution-Package-Jan2009.zip SRH-2D version 2.0 Distribution] includes SRH2D template files for both SMS 8.0 and SMS 10.0. | |||
== External Links == | |||
* [http://www.usbr.gov/pmts/sediment/model/srh2d/index.html Bureau of Reclamation SRH-2D Website] | |||
== External Links - SRH-2D Version 2.0 == | |||
* [http://www.usbr.gov/pmts/sediment/model/srh2d/Downloads/Manual-SRH2D-v2.0-Nov2008.pdf SRH-2D version 2.0 Theory and User Manual] | |||
* [http://www.usbr.gov/pmts/sediment/model/srh2d/Downloads/SRH2D-v2-Distribution-Package-Jan2009.zip SRH-2D version 2.0 Distribution] - Includes Software, Manual, Template file for integration into SMS interface, and Tutorials | |||
=== Papers / Presentations === | |||
* [http://www.usbr.gov/pmts/sediment/model/srh2d/Downloads/Theory_Paper-SRH2D-v2-2009.pdf SRH-2D Theory Paper] | |||
* [http://www.usbr.gov/pmts/sediment/model/srh2d/Downloads/SRH2D-v2-Training-Dec2007-Taiwan.pdf SRH-2D Training Presentation] | |||
* [http://www.usbr.gov/pmts/sediment/model/srh2d/Downloads/2005-US-China-Workshop-paper.pdf 2005 US-China Workshop Paper][http://www.usbr.gov/pmts/sediment/model/srh2d/Downloads/Paper%20US-China-Workshop%202005.pdf] | |||
* [http://www.usbr.gov/pmts/sediment/model/srh2d/Downloads/2006-Savage-Rapids-FISC-paper.pdf 2006 FISC Paper on Savage Rapids Dam Removal Project - "Comparison of Numerical Hydraulic Models Applied To The Removal of Savage Rapids Dam Near Grants Pass, Oregon"] | |||
* [http://www.usbr.gov/pmts/sediment/model/srh2d/Downloads/2006-April-GSTARW-Training.pdf FISC 2006 Short Course Presentation] | |||
* [http://www.usbr.gov/pmts/sediment/projects/Yakima/download/EWRIpaper_final_011307.pdf Using Bathymetric LiDAR and a 2-D Hydraulic Model to Identify Aquatic River Habitat] | |||
* [http://shira.lawr.ucdavis.edu/publications.htm List of journal articles using SMS by Prof. Greg Pasternack, UC Davis] | |||
=== Project Reports === | |||
* [http://www.usbr.gov/pmts/sediment/model/srh2d/Downloads/Final%20Report%20Savage%20Rapids%20Jan%2023%202006.pdf Bountry J.A. and Lai, Y.G. (2006)."Numerical modeling of flow hydraulics in support of the Savage Rapids Dam removal."] | |||
* [http://www.usbr.gov/pmts/sediment/model/srh2d/Downloads/Final%20Report%20Sandy%20River%20Report_031706.pdf Lai, Y.G., Holburn, E.R., and Bauer, T.R. (2006)."Analysis of sediment transport following removal of the Sandy River Delta Dam."] | |||
* [http://www.usbr.gov/pmts/sediment/model/srh2d/Downloads/Final%20Report-Elwha%20Nov%2014%202006.pdf Lai, Y.G. and Bountry, J.A. (2006). "Numerical hydraulic modeling and assessment in support of Elwha Surface Diversion Project."] | |||
* [http://www.usbr.gov/pmts/sediment/model/srh2d/Downloads/Final%20Report%20Dungeness%202dmodel%20report%20May7_07.pdf Lai, Y.G. and Bountry, J.A. (2007). "Numerical modeling study of levee setback alternatives for lower Dungeness River, Washington"] | |||
=== In the News === | |||
* [http://www.wired.com/science/discoveries/news/2007/07/dam Wired.com article "Computer Modeling Smoothes a Dam Hard Job"] | |||
* [http://www.wired.com/science/discoveries/multimedia/2007/07/dam_gallery?slide=1&slideView=10 Photos related to Wired.com article "Computer Modeling Smoothes a Dam Hard Job"] | |||
== External Links - SRH-W == | |||
=== SRH-W Version 1.1 === | |||
* [http://www.usbr.gov/pmts/sediment/model/srh2d/Downloads/SRH-W%20v1.1%20User%20Manual%20June2007.pdf SRH-W version 1.1 User Manual] | |||
* [http://www.usbr.gov/pmts/sediment/model/srh2d/Downloads/SRH-W1.1-Distribution-Package-2007.exe SRH-W version 1.1 Distribution Package] - Includes Software, Manual, and Tutorials | |||
=== Papers / Presentations === | |||
* [http://www.usbr.gov/pmts/sediment/model/srh2d/Downloads/2006-3rd-FIHMC-Paper-SRH-W.pdf 2006 FISC Watershed Modeling Paper - Watershed Simulation with an Enhanced Distributed Model][http://www.usbr.gov/pmts/sediment/model/srh2d/Downloads/Paper%20Watershed%20FISC%202006.pdf] | |||
== Related Topics == | |||
* [[SMS:Generic_Mesh_Model|Generic Model Interface]] | |||
{{Template:SMSMain}} | |||
[[Category:SMS 2D Mesh|S]] | |||
[[Category:SRH-2D|S]] | |||
Revision as of 18:09, 7 May 2011
| SRH-2D | |
|---|---|
| Model Info | |
| Model type | Two-dimensional (2D) hydraulic, sediment, temperature, and vegetation model for river systems |
| Developer |
Yong Lai |
| Web site | SRH-2D web site |
| Tutorials |
General Section
Models Section
|
About SRH-2D
SRH-2D, Sedimentation and River Hydraulics – Two-Dimensional model, is a two-dimensional (2D) hydraulic, sediment, temperature, and vegetation model for river systems under development at the Bureau of Reclamation. Different versions of SRH-2D contain different modules, as listed below (only version 2 is released and the rest will be released in the future):
- SRH-2D version 2: Modeling of flow hydraulics for stream/river systems
- SRH-2D version 3: Mobile bed sediment transport module added to v.2 (Not yet released)
- SRH-2D version 4: Temperature and vegetation module added to version v.2 (Not yet released)
- For watershed runoff modeling, SRH-W v.1.1 should be used.
About SRH-2D Version 2
SRH-2D version 2 solves the 2D dynamic wave equations, i.e., the depth-averaged St. Venant equations. Its modeling capability is comparable to some existing 2D models but SRH-2D claims a few boasting features. First, SRH-2D uses a flexible mesh that may contain arbitrarily shaped cells. In practice, the hybrid mesh of quadrilateral and triangular cells is recommended though purely quadrilateral or triangular elements may be used. A hybrid mesh may achieve the best compromise between solution accuracy and computing demand. Second, SRH-2D adopts very robust and stable numerical schemes with a seamless wetting-drying algorithm. The resultant outcome is that few tuning parameters are needed to obtain the final solution. SRH-2D was evolved from SRH-W which had the additional capability of watershed runoff modeling. Many features are improved from SRH-W.
Major Features of SRH-2D v. 2
Major SRH-2D capabilities are listed below
- 2D depth-averaged dynamic wave equations (the standard St. Venant equations) are solved with the finite-volume numerical method
- Steady state (with constant discharge) or unsteady flows (with flow hydrograph) may be simulated
- An implicit scheme is used for time integration to achieve solution robustness and efficiency
- An unstructured arbitrarily-shaped mesh is used which includes the structured quadrilateral mesh, the purely triangular mesh, or a combination of the two. Cartesian or raster mesh may also be used. In most applications, a combination of quadrilateral and triangular meshes is the best in terms of efficiency and accuracy
- All flow regimes, i.e., subcritical, transcritical, and supercritical flows, may be simulated simultaneously without the need for special treatments
- Robust and seamless wetting-drying algorithm; an
- Solved variables include water surface elevation, water depth, and depth averaged velocity. Output variables include the above, plus Froude number, bed shear stress, critical sediment diameter, and sediment transport capacity.
SRH-2D is a 2D model, and it is particularly useful for problems where 2D effects are important. Examples include flows with in-stream structures, through bends, with perched rivers, with side channel and agricultural returns, and with braided channel systems. A 2D model may also be needed if one is interested in local flow velocities, eddy patterns, flow recirculation, lateral velocity variation, and flow over banks and levees.
Features
- SRH-2D solves the 2D depth-averaged form of the diffusive wave or the dynamic wave equations. The dynamic wave equations are the standard St. Venant depth-averaged shallow water equations
- Both the diffusive wave and dynamic wave solvers use the implicit scheme to achieve solution robustness and efficiency
- Both steady or unsteady flows may be simulated
- All flow regimes, i.e., subcritical, transcritical, and supercritical flows, may be simulated simultaneously without the need of a special treatment
- Solution domain may include a combination of main channels, side channels, floodplains, and overland
- Solved variables include water surface elevation, water depth, and depth averaged velocity. Output information includes above variables, plus flow inundation, Froude number, and bed shear stress
SRH-2D is a 2D model and it is particularly useful for problems where 2D effects are important. Examples include flows with in-stream structures, through bends, with perched rivers, with multiple channel systems, and with complex floodplains. A 2D model may also be needed if one is interested in local flow velocities, eddy patterns and flow recirculation, lateral variations, flow spills over banks and levees, and flow diversion and bifurcation.
The Bureau of Reclamation does not provide technical support for SRH-2D.
Graphical Interface
SRH-2D uses the Generic Model Graphical Interface. The SRH-2D version 2.0 Distribution includes SRH2D template files for both SMS 8.0 and SMS 10.0.
External Links
External Links - SRH-2D Version 2.0
- SRH-2D version 2.0 Theory and User Manual
- SRH-2D version 2.0 Distribution - Includes Software, Manual, Template file for integration into SMS interface, and Tutorials
Papers / Presentations
- SRH-2D Theory Paper
- SRH-2D Training Presentation
- 2005 US-China Workshop Paper[1]
- 2006 FISC Paper on Savage Rapids Dam Removal Project - "Comparison of Numerical Hydraulic Models Applied To The Removal of Savage Rapids Dam Near Grants Pass, Oregon"
- FISC 2006 Short Course Presentation
- Using Bathymetric LiDAR and a 2-D Hydraulic Model to Identify Aquatic River Habitat
- List of journal articles using SMS by Prof. Greg Pasternack, UC Davis
Project Reports
- Bountry J.A. and Lai, Y.G. (2006)."Numerical modeling of flow hydraulics in support of the Savage Rapids Dam removal."
- Lai, Y.G., Holburn, E.R., and Bauer, T.R. (2006)."Analysis of sediment transport following removal of the Sandy River Delta Dam."
- Lai, Y.G. and Bountry, J.A. (2006). "Numerical hydraulic modeling and assessment in support of Elwha Surface Diversion Project."
- Lai, Y.G. and Bountry, J.A. (2007). "Numerical modeling study of levee setback alternatives for lower Dungeness River, Washington"
In the News
- Wired.com article "Computer Modeling Smoothes a Dam Hard Job"
- Photos related to Wired.com article "Computer Modeling Smoothes a Dam Hard Job"
External Links - SRH-W
SRH-W Version 1.1
- SRH-W version 1.1 User Manual
- SRH-W version 1.1 Distribution Package - Includes Software, Manual, and Tutorials
Papers / Presentations
Related Topics
Modules: Mesh Module · Cartesian Grid Module · Scatter Module · Map Module · GIS Module · Particle Module
Models: ADCIRC · BOUSS-2D · CGWAVE · CMS-Flow · CMS-Wave · FESWMS · FVCOM · Generic Mesh Model · GENESIS · HYDRO AS-2D · PTM · SRH-2D · Steering · STWAVE · TABS · TUFLOW
