SMS:SRH-2D Coverages: Difference between revisions
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The SRH-2D model makes use of the simulation based modeling approach. This requires defining [[SMS:Coverages|coverages]] in the [[SMS:Map Module|Map module]] to build the components for use in the SRH-2D [[SMS:Simulations|simulation]]. | The SRH-2D model makes use of the simulation based modeling approach. This requires defining [[SMS:Coverages|coverages]] in the [[SMS:Map Module|Map module]] to build the components for use in the SRH-2D [[SMS:Simulations|simulation]]. | ||
==Boundary Conditions Coverage== | ==Boundary Conditions Coverage== | ||
==== Mobile Run Type ==== | ==== Mobile Run Type ==== | ||
The "Mobile" option is used to perform a sediment transport simulation. It should be noted that sediment transport simulations require a hotstart or restart file from a corresponding hydraulic simulation. When the "Mobile" option is specified the dialog expands to include sediment transport parameters. | The "Mobile" option is used to perform a sediment transport simulation. It should be noted that sediment transport simulations require a hotstart or restart file from a corresponding hydraulic simulation. When the "Mobile" option is specified the dialog expands to include sediment transport parameters. | ||
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=== Boundary Conditions === | === Boundary Conditions === | ||
[[File: | [[File:SRH2D_Assign_BC.PNG|thumb|400 px|The SRH-2D ''Linear BC'' dialog showing a the Inlet-Q option.]] | ||
SRH-2D | SRH-2D supports a variety of boundary conditions for hydraulic computation. The boundary conditions for the model are specified through the SRH-2D Boundary Condition coverage by selecting an arc. In SMS 11.2 and earlier versions, a boundary could also be defined by selecting a nodestring in the mesh instead, though this is no longer supported in SMS 12.0 and later versions. Once the arc or nodestring has been selected, double-clicking, or right-clicking and using the '''Assign BC...''' command, will bring up a dialog where the boundaries can be assigned. | ||
All currently supported boundary types are exterior boundaries that must be placed on the mesh boundary with the exception of a monitor line. Other boundary types include the following: Inlet-Q, Inlet-SC, Exit-EX, Exit-H, Exit-Q, Wall, and Symmetry. | All currently supported boundary types are exterior boundaries that must be placed on the mesh boundary with the exception of a monitor line. Other boundary types include the following: Inlet-Q, Inlet-SC, Exit-EX, Exit-H, Exit-Q, Wall, and Symmetry. | ||
BC Types: | |||
*Inlet-Q is a subcritical inlet boundary that may be given as a constant discharge or as a variable discharge hydrograph. The velocity distribution type may be selected from the boundary condition menu. Inlet flow volume values can only be positive. For a sediment transport run, the inflowing sediment loads are also specified. | *Inlet-Q is a subcritical inlet boundary that may be given as a constant discharge or as a variable discharge hydrograph. The velocity distribution type may be selected from the boundary condition menu. Inlet flow volume values can only be positive. For a sediment transport run, the inflowing sediment loads are also specified. | ||
*Inlet-SC is a supercritical inlet boundary that may be given as a constant discharge or as a variable discharge hydrograph. Inlet-SC also requires information about depth. Within the boundary condition menu, the velocity distribution type may be specified. Inlet flow volume values can only be positive. For a sediment transport run, the inflowing sediment loads are also specified. | *Inlet-SC is a supercritical inlet boundary that may be given as a constant discharge or as a variable discharge hydrograph. Inlet-SC also requires information about depth. Within the boundary condition menu, the velocity distribution type may be specified. Inlet flow volume values can only be positive. For a sediment transport run, the inflowing sediment loads are also specified. | ||
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* [[SMS:SRH-2D Structures#Internal Sink|Internal Sink]] – Models a drain or sink inside the model domain. | * [[SMS:SRH-2D Structures#Internal Sink|Internal Sink]] – Models a drain or sink inside the model domain. | ||
* [[SMS:SRH-2D Structures#Link|Link]] – Models flow between two separate meshes. | * [[SMS:SRH-2D Structures#Link|Link]] – Models flow between two separate meshes. | ||
* [[SMS:SRH-2D_Structures#BC Data|BC Data]] – Options for specifying BCDATA lines and flow direction. | |||
See [[SMS:SRH-2D Boundary Conditions|SRH-2D Boundary Conditions]] for more information on the options for each boundary type. | See [[SMS:SRH-2D Boundary Conditions|SRH-2D Boundary Conditions]] for more information on the options for each boundary type. | ||
[[Category:SMS Boundary Conditions|SRH-2D]] | [[Category:SMS Boundary Conditions|SRH-2D]] | ||
==Obstructions Coverage== | ==Obstructions Coverage== | ||
[[File: | [[File:SRH2D Assign Obstructions.png|thumb|400 px|The ''SRH-2D Assign Obstruction'' dialog]] | ||
Used to create feature objects that represent obstructions, such as bank protrusions and boulder clusters. Obstructions can be assigned to feature arcs or points. | Used to create feature objects that represent obstructions, such as bank protrusions and boulder clusters. Obstructions can be assigned to feature arcs or points. | ||
The elevation that is assigned to the point (for point obstructions) or nodes and vertices (for arc (line) obstructions) will be used as the bottom elevation of the obstruction. If the elevation from node to vertex or vertex to vertex along an arc (line) obstruction is different, the average of the two elevations will be used as the bottom elevation of the obstruction for that "span" of the arc. | The elevation that is assigned to the point (for point obstructions) or nodes and vertices (for arc (line) obstructions) will be used as the bottom elevation of the obstruction. If the elevation from node to vertex or vertex to vertex along an arc (line) obstruction is different, the average of the two elevations will be used as the bottom elevation of the obstruction for that "span" of the arc. | ||
When this coverage is active, double-clicking on a feature arc or point, or right-clicking on an arc or point followed by selecting the '''Assign | When this coverage is active, double-clicking on a feature arc or point, or right-clicking on an arc or point followed by selecting either the '''Assign Arc Obstruction''' or the '''Assign Point Obstruction''' command will bring up the ''SRH-2D Assign Obstruction'' dialog. | ||
The '' | The ''SRH-2D Assign Obstruction'' dialog has the following options: | ||
* '' | * ''Width/Diameter'' – Each arc segment represents a rectangular area based on the assigned width. Each point represents a circular diameter based on the assigned width. | ||
* '' | * ''Thickness (Z-dir)'' – Represents the vertical thickness of the obstruction. | ||
* ''Drag Coefficient (Cd)'' – A dimensionless coefficient used to describe the surface upon which the water will be flowing around. See the table below. | * ''Drag Coefficient (Cd)'' – A dimensionless coefficient used to describe the surface upon which the water will be flowing around. See the table below. | ||
*''Units'' – May be assigned to either "ft" (feet) or "m" (meters). | *''Units'' – May be assigned to either "ft" (feet) or "m" (meters). | ||
* ''Porosity'' – Represents the ability for water to flow through the obstruction object. A porosity of 0 represents a solid surface with no pores allowing for water to pass through the object and 1 represents a surface comparable to a wire mesh with many holes allowing water to pass through it. | * ''Porosity'' – Represents the fraction of the projected area that is void, where 0.0 porosity represents a solid. <!--Represents the ability for water to flow through the obstruction object. A porosity of 0 represents a solid surface with no pores allowing for water to pass through the object and 1 represents a surface comparable to a wire mesh with many holes allowing water to pass through it.--> | ||
{| class="wikitable" | {| class="wikitable" | ||
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|Long flat plate at 90° || 1.98 || | |Long flat plate at 90° || 1.98 || | ||
|} | |} | ||
Please refer to the SRH-2D user manual for additional details on how obstructions are applied in a model. | |||
==Monitor Coverage== | ==Monitor Coverage== | ||
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*The former Boundary Condition coverage will be made into two coverages, one for the monitor lines and the other for the existing boundary conditions. The names of these coverages will have either "Boundary Conditions" or "Monitor" attached to designate which coverage contains the boundary condition arcs and which contains the monitor lines. | *The former Boundary Condition coverage will be made into two coverages, one for the monitor lines and the other for the existing boundary conditions. The names of these coverages will have either "Boundary Conditions" or "Monitor" attached to designate which coverage contains the boundary condition arcs and which contains the monitor lines. | ||
*If a Monitor Points coverage existed in the project, this coverage will be changed to a Monitor coverage and the coverage name will have "Monitor" attached. | *If a Monitor Points coverage existed in the project, this coverage will be changed to a Monitor coverage and the coverage name will have "Monitor" attached. | ||
*If the imported project had both monitor points and monitor lines, | *If the imported project had both monitor points and monitor lines, there will now be a Monitor coverage for each Monitor Points coverage and a Monitor coverage for each Boundary Condition coverage that contained monitor lines. | ||
*By default, the Monitor coverage with the monitor lines will be included in any simulations. | *By default, the Monitor coverage with the monitor lines will be included in any simulations. | ||
*The monitor points and monitor lines from the previous project will need to be merged into one Monitor coverage and linked to the simulation in order for both points and lines to be included in the simulation run. | *The monitor points and monitor lines from the previous project will need to be merged into one Monitor coverage and linked to the simulation in order for both points and lines to be included in the simulation run. | ||
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===Monitor Points=== | ===Monitor Points=== | ||
If choosing to have monitor points, add points using the '''Create Feature Point''' tool in the Monitor coverage. A monitor point is used to gather specific information for that location at all time steps. Information calculated by SRH-2D at a monitor point includes position in the X and Y direction, bed elevation, water elevation, water depth, X direction velocity component, Y direction velocity component, velocity magnitude, Froude number, and shear stress. This data is written to a separate output file for each monitor point. These files appear in the output directory and are called PT(''n'').dat, where ''n'' is a sequential integer corresponding to the order of the SMS feature point ID numbers for the monitor points. | If choosing to have monitor points, add points using the '''Create Feature Point''' tool in the Monitor coverage. A monitor point is used to gather specific information for that location at all time steps. Information calculated by SRH-2D at a monitor point includes position in the X and Y direction, bed elevation, water elevation, water depth, X direction velocity component, Y direction velocity component, velocity magnitude, Froude number, and shear stress. This data is written to a separate output file for each monitor point. These files appear in the output directory and are called PT(''n'').dat, where ''n'' is a sequential integer corresponding to the order of the SMS feature point ID numbers for the monitor points. | ||
To ensure the ID number will match the numbers appended to the data files, it is recommended that the following be done: | |||
* Create all monitor points before creating monitor lines. | |||
* Renumber the Monitor coverage before running SRH-2D. | |||
For a sediment transport simulation, the D50 particle size is included in the monitor point output file, and an additional sediment monitor point file is created that includes concentration, erosion and deposition, and bed material gradations. | For a sediment transport simulation, the D50 particle size is included in the monitor point output file, and an additional sediment monitor point file is created that includes concentration, erosion and deposition, and bed material gradations. | ||
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===Monitor Lines=== | ===Monitor Lines=== | ||
Monitor Lines are created to extract data from the solution along an arc. Monitor lines are optional, but highly recommended to help verify continuity and model stability | Monitor Lines are created to extract data from the solution along an arc. Monitor lines are optional, but highly recommended to help verify continuity and model stability. SRH-2D will calculate the total flow across the arc and the average water surface elevation along the arc. | ||
Monitor line output is written to a separate output file for each monitor line. These files will appear in the output directory and are called LN(''n'').dat, where ''n'' is a sequential integer corresponding to the order of the SMS feature arc ID numbers. Once steady state is achieved, flows reported in these files corresponding to monitor lines placed near the outflow should be very close to the total inflow. Also, reviewing the flow and WSE values reported in these files at the final time steps can help verify model stability. Unstable models may show varying or oscillating values for the flows reported for the monitor line. | Create monitor lines using the '''Create Feature Arc''' tool, and digitizing arcs in the Monitor coverage. Create the arcs in the Monitor coverage at locations where it is desirable to compute flow. The direction of the monitor line does not matter, except that flow values will be reported as positive or negative if the line creation direction is reversed. It is recommended that monitor lines be created near the inflow and outflow boundaries. Monitor lines must be created inside the domain and not outside the domain or on the edge of the domain. Monitoring flows near the outflow boundary can help verify model continuity. Monitor lines are also useful for evaluating flow splits or other areas where the flow across a line is desirable. | ||
Monitor line output is written to a separate output file for each monitor line. These files will appear in the output directory and are called LN(''n'').dat, where ''n'' is a sequential integer corresponding to the order of the SMS feature arc ID numbers. The monitor lines are save sequentially from how they are encountered in by the SRH-2D model run. Displaying the ID numbers in the Monitor coverage will show the order. | |||
To ensure the ID number will match the numbers appended to the data files, it is recommended that the following be done: | |||
* Create all monitor points before creating monitor lines. | |||
* Renumber the Monitor coverage before running SRH-2D. | |||
Once steady state is achieved, flows reported in these files corresponding to monitor lines placed near the outflow should be very close to the total inflow. Also, reviewing the flow and WSE values reported in these files at the final time steps can help verify model stability. Unstable models may show varying or oscillating values for the flows reported for the monitor line. | |||
==Materials Coverage== | ==Materials Coverage== | ||
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===Materials Coverage Right-Click Menu=== | ===Materials Coverage Right-Click Menu=== | ||
The materials coverage has the standard [[SMS:Map_Project_Explorer#Coverage Item Right-Click Menus|coverage item right-click menu commands]] as well as specific right-click commands. The following commands are also part of the SRH-2D materials coverage: | The materials coverage has the standard [[SMS:Map_Project_Explorer#Coverage Item Right-Click Menus|coverage item right-click menu commands]] as well as specific right-click commands. The following commands are also part of the SRH-2D materials coverage: | ||
*[[SMS:SRH-2D Material Properties|'''Material Properties''']] – Opens the ''Material Properties'' dialog. | *[[SMS:SRH-2D Material Properties|'''Material List and Properties''']] – Opens the ''Material List and Properties'' dialog. | ||
*'''Assign Material | *'''Assign Material''' – Opens the ''Assign Material'' dialog for managing multiple material coverages. | ||
===Assign Materials=== | ===Assign Materials=== | ||
[[File: | [[File:Assign_Material_Dialog.PNG|thumb|250 px|Example of the ''Assign Materials'' dialog.]] | ||
SRH-2D allows the option to have multiple material coverages. When multiple material coverages exist, there are options to manage these coverages. By right-clicking on an SRH-2D materials coverage and selecting the '''Assign | SRH-2D allows the option to have multiple material coverages. When multiple material coverages exist, there are options to manage these coverages. By right-clicking on an SRH-2D materials coverage and selecting the '''Assign Material''' command, the ''Assign Materials'' dialog can be accessed. This dialog allows adding the unique material definition of one material coverage to that of another material coverage. Select the target material coverage that will be modified by the material coverage used to access the dialog. There are a number of options available for the coverage selections. | ||
* | *"Flood Plain" – Represents a flood plain. | ||
* | *"Unassigned" – Represents an unassigned coverage. | ||
*"Road" – Represents a road. | |||
*"River" – Represents a river. | |||
After performing either of these actions, opening the ''Material Properties'' dialog for the target material coverage will show the material list modified with the new definitions. | After performing either of these actions, opening the ''Material Properties'' dialog for the target material coverage will show the material list modified with the new definitions. | ||
===Assigning Materials to Polygons=== | ===Assigning Materials to Polygons=== | ||
Materials can be assigned to individual polygons using the '''Select Polygon''' tool and double-clicking on a polygon in the materials coverage. This will bring up the ''Assign Material | Materials can be assigned to individual polygons using the '''Select Polygon''' tool and double-clicking on a polygon in the materials coverage. This will bring up the ''Assign Material'' dialog. | ||
The ''Assign Material | The ''Assign Material'' dialog can also be reached by right-clicking on a polygon in the materials coverage and selecting the '''Assign Material''' command. | ||
See [[SMS:SRH-2D Material Properties|SRH-2D Material Properties]] for more information about the ''Assign Material | See [[SMS:SRH-2D Material Properties|SRH-2D Material Properties]] for more information about the ''Assign Material'' dialog. | ||
==Sediment Materials Coverage== | ==Sediment Materials Coverage== | ||
The SRH-2D Sediment Materials coverage is similar to the Materials coverage, however, the materials zones in this coverage assign sediment properties. The coverage has the same right-click menu options as the Materials coverage. Sediment materials are assigned to polygons. Sediment layer thicknesses, gradations, and bulk densities (in dry unit weights in lb/ft<sup>3</sup> or kg/m<sup>3</sup>) are provided for each layer. A non-erodible material can be specified by leaving the layer information blank. | The SRH-2D Sediment Materials coverage is similar to the Materials coverage, however, the materials zones in this coverage assign sediment properties. The coverage has the same right-click menu options as the Materials coverage. | ||
Sediment materials are assigned to polygons. The polygons are then [[SMS:Snapping#Snap_Preview_of_Feature_Objects_to_a_Geometry|"snapped"]] to the mesh elements during the model run. If the border of a polygon falls on the centroid of an elementa, it will be unassigned. If this happens, SMS will give a warning when launching the simulation. This warning can be ignored in some cases, such as when the cell is a fringe cell or when cells are intentionally disabled, but this is up to the user's discretion. | |||
Sediment layer thicknesses, gradations, and bulk densities (in dry unit weights in lb/ft<sup>3</sup> or kg/m<sup>3</sup>) are provided for each layer. A non-erodible material can be specified by leaving the layer information blank. | |||
For more information, see the [[SMS:SRH-2D Sediment Material Properties| Sediment Material Properties]] article. | For more information, see the [[SMS:SRH-2D Sediment Material Properties| Sediment Material Properties]] article. |
Latest revision as of 16:21, 24 September 2024
The SRH-2D model makes use of the simulation based modeling approach. This requires defining coverages in the Map module to build the components for use in the SRH-2D simulation.
Boundary Conditions Coverage
Mobile Run Type
The "Mobile" option is used to perform a sediment transport simulation. It should be noted that sediment transport simulations require a hotstart or restart file from a corresponding hydraulic simulation. When the "Mobile" option is specified the dialog expands to include sediment transport parameters.
The sediment transport options are described in the SRH-2D Sediment Transport Parameters article.
Boundary Conditions
SRH-2D supports a variety of boundary conditions for hydraulic computation. The boundary conditions for the model are specified through the SRH-2D Boundary Condition coverage by selecting an arc. In SMS 11.2 and earlier versions, a boundary could also be defined by selecting a nodestring in the mesh instead, though this is no longer supported in SMS 12.0 and later versions. Once the arc or nodestring has been selected, double-clicking, or right-clicking and using the Assign BC... command, will bring up a dialog where the boundaries can be assigned.
All currently supported boundary types are exterior boundaries that must be placed on the mesh boundary with the exception of a monitor line. Other boundary types include the following: Inlet-Q, Inlet-SC, Exit-EX, Exit-H, Exit-Q, Wall, and Symmetry. BC Types:
- Inlet-Q is a subcritical inlet boundary that may be given as a constant discharge or as a variable discharge hydrograph. The velocity distribution type may be selected from the boundary condition menu. Inlet flow volume values can only be positive. For a sediment transport run, the inflowing sediment loads are also specified.
- Inlet-SC is a supercritical inlet boundary that may be given as a constant discharge or as a variable discharge hydrograph. Inlet-SC also requires information about depth. Within the boundary condition menu, the velocity distribution type may be specified. Inlet flow volume values can only be positive. For a sediment transport run, the inflowing sediment loads are also specified.
- Exit-EX is a supercritical exit boundary condition.
- Exit-H is a stage type exit boundary where water surface elevation may be given as a constant number or as a stage-discharge or rating curve. Using a constant or rating curve allows accessing the Populate dialog.
- Exit-Q is an exit boundary with a discharge given as a constant number or as a hydrograph.
- Wall
- Symmetry is defined as a boundary where all dependent variables are extrapolated assuming the gradient of the variable in a direction normal to the boundary is zero except the velocity component normal to the boundary.
- Monitor-Line it is an internal polyline which may be used to monitor the total flow discharge and average water surface elevation. For a sediment transport simulation, the total sediment discharge, concentration, average bed elevation, and sediment discharges by size fraction are added to this output.
- Weir – See the SRH-2D Structures article for more information.
- Culvert – See the SRH-2D Structures article for more information.
- Pressure zone – See the SRH-2D Structures article for more information.
- Gate – See the SRH-2D Structures article for more information.
- Internal Sink – Models a drain or sink inside the model domain.
- Link – Models flow between two separate meshes.
- BC Data – Options for specifying BCDATA lines and flow direction.
See SRH-2D Boundary Conditions for more information on the options for each boundary type.
Obstructions Coverage
Used to create feature objects that represent obstructions, such as bank protrusions and boulder clusters. Obstructions can be assigned to feature arcs or points.
The elevation that is assigned to the point (for point obstructions) or nodes and vertices (for arc (line) obstructions) will be used as the bottom elevation of the obstruction. If the elevation from node to vertex or vertex to vertex along an arc (line) obstruction is different, the average of the two elevations will be used as the bottom elevation of the obstruction for that "span" of the arc.
When this coverage is active, double-clicking on a feature arc or point, or right-clicking on an arc or point followed by selecting either the Assign Arc Obstruction or the Assign Point Obstruction command will bring up the SRH-2D Assign Obstruction dialog.
The SRH-2D Assign Obstruction dialog has the following options:
- Width/Diameter – Each arc segment represents a rectangular area based on the assigned width. Each point represents a circular diameter based on the assigned width.
- Thickness (Z-dir) – Represents the vertical thickness of the obstruction.
- Drag Coefficient (Cd) – A dimensionless coefficient used to describe the surface upon which the water will be flowing around. See the table below.
- Units – May be assigned to either "ft" (feet) or "m" (meters).
- Porosity – Represents the fraction of the projected area that is void, where 0.0 porosity represents a solid.
Type of Object | Drag Coefficient | Frontal Area – A |
---|---|---|
Long stream-lined body | 0.1 | |
Hollow semi-sphere facing stream | 0.38 | |
Solid hemisphere | 0.42 | π / 4 d2 |
Sphere | 0.5 | |
Cube | 0.8 | |
Thin disk | 1.1 | π / 4 d2 |
Squared flat plate at 90° | 1.17 | |
Circular cylinder | 1.0–1.3 | |
Hollow semi-cylinder opposite stream | 1.2 | |
Long flat plate at 90° | 1.98 |
Please refer to the SRH-2D user manual for additional details on how obstructions are applied in a model.
Monitor Coverage
Monitor points and lines are optional.
If a Monitor coverage has been created, then it must be linked to the SRH-2D simulation. This can be done by dragging the coverage under the simulation item in the Project Explorer or right-clicking on the coverage and using the Link to menu item. When the simulation is launched, monitoring point and line data will be collected and outputted.
In SMS 11.2 only, the Monitor Points coverage must be assigned and selected in the Select the Monitor Point Coverage dialog for SRH-2D to recognize them. The dialog is accessed through the Assign Monitor Points Coverage command in the SRH-2D menu. This process is obsolete in SMS 12.0 and higher.
Starting in SMS version 13.0, monitor lines are no longer set on the Boundary Conditions coverage. Because of this change, when importing SRH-2D projects create in earlier versions of SMS several items will happen:
- SMS will separate the monitoring lines from other arcs in the boundary conditions coverage. The monitoring lines will be placed in their own Monitor coverage.
- The former Boundary Condition coverage will be made into two coverages, one for the monitor lines and the other for the existing boundary conditions. The names of these coverages will have either "Boundary Conditions" or "Monitor" attached to designate which coverage contains the boundary condition arcs and which contains the monitor lines.
- If a Monitor Points coverage existed in the project, this coverage will be changed to a Monitor coverage and the coverage name will have "Monitor" attached.
- If the imported project had both monitor points and monitor lines, there will now be a Monitor coverage for each Monitor Points coverage and a Monitor coverage for each Boundary Condition coverage that contained monitor lines.
- By default, the Monitor coverage with the monitor lines will be included in any simulations.
- The monitor points and monitor lines from the previous project will need to be merged into one Monitor coverage and linked to the simulation in order for both points and lines to be included in the simulation run.
- The default boundary condition for arcs on an SRH-2D boundary condition coverage is now the "Wall" type. The boundary condition arcs should be reviewed to ensure no parameters were lost in the conversion.
Monitor Points
If choosing to have monitor points, add points using the Create Feature Point tool in the Monitor coverage. A monitor point is used to gather specific information for that location at all time steps. Information calculated by SRH-2D at a monitor point includes position in the X and Y direction, bed elevation, water elevation, water depth, X direction velocity component, Y direction velocity component, velocity magnitude, Froude number, and shear stress. This data is written to a separate output file for each monitor point. These files appear in the output directory and are called PT(n).dat, where n is a sequential integer corresponding to the order of the SMS feature point ID numbers for the monitor points.
To ensure the ID number will match the numbers appended to the data files, it is recommended that the following be done:
- Create all monitor points before creating monitor lines.
- Renumber the Monitor coverage before running SRH-2D.
For a sediment transport simulation, the D50 particle size is included in the monitor point output file, and an additional sediment monitor point file is created that includes concentration, erosion and deposition, and bed material gradations.
Usually, one monitor point will be created near the outflow boundary and another near the inflow or perhaps near an area of interest. Water levels for the first two monitor points created will be displayed during the model run.
Monitor Lines
Monitor Lines are created to extract data from the solution along an arc. Monitor lines are optional, but highly recommended to help verify continuity and model stability. SRH-2D will calculate the total flow across the arc and the average water surface elevation along the arc.
Create monitor lines using the Create Feature Arc tool, and digitizing arcs in the Monitor coverage. Create the arcs in the Monitor coverage at locations where it is desirable to compute flow. The direction of the monitor line does not matter, except that flow values will be reported as positive or negative if the line creation direction is reversed. It is recommended that monitor lines be created near the inflow and outflow boundaries. Monitor lines must be created inside the domain and not outside the domain or on the edge of the domain. Monitoring flows near the outflow boundary can help verify model continuity. Monitor lines are also useful for evaluating flow splits or other areas where the flow across a line is desirable.
Monitor line output is written to a separate output file for each monitor line. These files will appear in the output directory and are called LN(n).dat, where n is a sequential integer corresponding to the order of the SMS feature arc ID numbers. The monitor lines are save sequentially from how they are encountered in by the SRH-2D model run. Displaying the ID numbers in the Monitor coverage will show the order.
To ensure the ID number will match the numbers appended to the data files, it is recommended that the following be done:
- Create all monitor points before creating monitor lines.
- Renumber the Monitor coverage before running SRH-2D.
Once steady state is achieved, flows reported in these files corresponding to monitor lines placed near the outflow should be very close to the total inflow. Also, reviewing the flow and WSE values reported in these files at the final time steps can help verify model stability. Unstable models may show varying or oscillating values for the flows reported for the monitor line.
Materials Coverage
The SRH-2D materials coverage allows creating material zones specific to the SRH-2D model. The materials zones must cover the domain extents of the project.
Materials Coverage Right-Click Menu
The materials coverage has the standard coverage item right-click menu commands as well as specific right-click commands. The following commands are also part of the SRH-2D materials coverage:
- Material List and Properties – Opens the Material List and Properties dialog.
- Assign Material – Opens the Assign Material dialog for managing multiple material coverages.
Assign Materials
SRH-2D allows the option to have multiple material coverages. When multiple material coverages exist, there are options to manage these coverages. By right-clicking on an SRH-2D materials coverage and selecting the Assign Material command, the Assign Materials dialog can be accessed. This dialog allows adding the unique material definition of one material coverage to that of another material coverage. Select the target material coverage that will be modified by the material coverage used to access the dialog. There are a number of options available for the coverage selections.
- "Flood Plain" – Represents a flood plain.
- "Unassigned" – Represents an unassigned coverage.
- "Road" – Represents a road.
- "River" – Represents a river.
After performing either of these actions, opening the Material Properties dialog for the target material coverage will show the material list modified with the new definitions.
Assigning Materials to Polygons
Materials can be assigned to individual polygons using the Select Polygon tool and double-clicking on a polygon in the materials coverage. This will bring up the Assign Material dialog.
The Assign Material dialog can also be reached by right-clicking on a polygon in the materials coverage and selecting the Assign Material command.
See SRH-2D Material Properties for more information about the Assign Material dialog.
Sediment Materials Coverage
The SRH-2D Sediment Materials coverage is similar to the Materials coverage, however, the materials zones in this coverage assign sediment properties. The coverage has the same right-click menu options as the Materials coverage.
Sediment materials are assigned to polygons. The polygons are then "snapped" to the mesh elements during the model run. If the border of a polygon falls on the centroid of an elementa, it will be unassigned. If this happens, SMS will give a warning when launching the simulation. This warning can be ignored in some cases, such as when the cell is a fringe cell or when cells are intentionally disabled, but this is up to the user's discretion.
Sediment layer thicknesses, gradations, and bulk densities (in dry unit weights in lb/ft3 or kg/m3) are provided for each layer. A non-erodible material can be specified by leaving the layer information blank.
For more information, see the Sediment Material Properties article.
Related Topics
SMS – Surface-water Modeling System | ||
---|---|---|
Modules: | 1D Grid • Cartesian Grid • Curvilinear Grid • GIS • Map • Mesh • Particle • Quadtree • Raster • Scatter • UGrid | |
General Models: | 3D Structure • FVCOM • Generic • PTM | |
Coastal Models: | ADCIRC • BOUSS-2D • CGWAVE • CMS-Flow • CMS-Wave • GenCade • STWAVE • WAM | |
Riverine/Estuarine Models: | AdH • HEC-RAS • HYDRO AS-2D • RMA2 • RMA4 • SRH-2D • TUFLOW • TUFLOW FV | |
Aquaveo • SMS Tutorials • SMS Workflows |