WMS:HEC-HMS Defining the Meteorological Model: Difference between revisions
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Define meteorologic data for the model by selecting the '''Meteorologic Parameters''' menu item from the ''HEC-HMS'' menu. | Define meteorologic data for the model by selecting the '''Meteorologic Parameters''' menu item from the ''HEC-HMS'' menu. | ||
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Selecting this menu item will bring up the ''HMS Meteorological Model'' dialog. This dialog is used to assign precipitation data to all the basins in the model. | Selecting this menu item will bring up the ''HMS Meteorological Model'' dialog. This dialog is used to assign precipitation data to all the basins in the model. | ||
:[[File:HMSUserHyetograph1. | :[[File:HMSUserHyetograph1.png|thumb|none|left|500 px|''HMS Meteorological Model'' dialog]] | ||
The same precipitation method must be assigned to all the basins in the HMS model. The precipitation method | The same precipitation method must be assigned to all the basins in the HMS model. The precipitation method chosen should be based on the type of analysis to be run. If having rainfall gage data for the watershed, use the user hyetograph or the user gage weighting method. If wanting to create a synthetic storm with a known exceedance probability, select the frequency storm method. If wanting to model a standard project storm, select the standard project storm or the SCS hypothetical storm method. Only use the ''No Precipitation'' option if the HMS model does not have any basins. See the topics below for more detailed information about the ''HMS Meteorological Model'' dialog. | ||
==HEC-HMS User Hyetograph== | ==HEC-HMS User Hyetograph== | ||
The User Hyetograph method can be used if a hyetograph is known for each sub-basin of the watershed being modeled. Get this hyetograph from recorded data or from any other method. Enter the same or different hyetographs for each basin, but each basin can only have a single hyetograph. Define the hyetograph by clicking on the '''XY Series''' button in the ''HMS Meteorological Model'' dialog shown below, and define the hyetograph in the XY series editor: | The User Hyetograph method can be used if a hyetograph is known for each sub-basin of the watershed being modeled. Get this hyetograph from recorded data or from any other method. Enter the same or different hyetographs for each basin, but each basin can only have a single hyetograph. Define the hyetograph by clicking on the '''XY Series''' button in the ''HMS Meteorological Model'' dialog shown below, and define the hyetograph in the XY series editor: | ||
:[[Image:HMSUserHyetograph1. | :[[Image:HMSUserHyetograph1.png|thumb|none|left|500 px|''HMS Meteorological Model'' dialog for the "User Hyetograph" method.]] | ||
==Standard Project Storm== | ==Standard Project Storm== | ||
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Get the index precipitation value (also known as the probable maximum index precipitation) from HYDROMET Report 33. It can also be estimated from plates contained in EM 1110-2-1411 (US Army Corps of Engineers) and represents the total precipitation depth for the storm. The storm area is the total drainage area at the point where the standard project flood is to be estimated. For the temporal distribution type, the standard storm distributes the precipitation according to the criteria outlined in EM 1110-2-1411. The "SWD" option distributes precipitation according to the Southwestern Division criteria (table 3.1 of the HEC-1 reference manual). | Get the index precipitation value (also known as the probable maximum index precipitation) from HYDROMET Report 33. It can also be estimated from plates contained in EM 1110-2-1411 (US Army Corps of Engineers) and represents the total precipitation depth for the storm. The storm area is the total drainage area at the point where the standard project flood is to be estimated. For the temporal distribution type, the standard storm distributes the precipitation according to the criteria outlined in EM 1110-2-1411. The "SWD" option distributes precipitation according to the Southwestern Division criteria (table 3.1 of the HEC-1 reference manual). | ||
Each basin requires a transposition factor. The transposition factor for each | Each basin requires a transposition factor. The transposition factor for each sub-basin can range from 0.80 to 1.40 and is multiplied by the index precipitation to determine the mean areal precipitation. The transposition factor can be determined from the SPS isohyetal pattern contained in EM 1110-2-1411 and a map of the watershed. | ||
===Reference=== | ===Reference=== | ||
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"The frequency storm method can be used to create a balanced, synthetic storm with a known exceedance probability. Automatic adjustments for storm area and series type are based on the exceedance probability. Depth-duration data are usually obtained from publications such as TP-40 (National Weather Service, 1961)." (HEC-HMS User's Manual) The options for defining a frequency storm are shown below: | "The frequency storm method can be used to create a balanced, synthetic storm with a known exceedance probability. Automatic adjustments for storm area and series type are based on the exceedance probability. Depth-duration data are usually obtained from publications such as TP-40 (National Weather Service, 1961)." (HEC-HMS User's Manual) The options for defining a frequency storm are shown below: | ||
[[Image:HMSFrequencyStorm1. | [[Image:HMSFrequencyStorm1.png|thumb|none|left|550 px|''HMS Meteorological Model'' dialog for the "Frequency Storm" method.]] | ||
Follow the following steps (from the HEC-HMS User's Manual) to set up a frequency storm: | Follow the following steps (from the HEC-HMS User's Manual) to set up a frequency storm: | ||
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This method does not perform any depth-area reductions. The ''HMS Meteorological Model'' dialog for this method is shown below: | This method does not perform any depth-area reductions. The ''HMS Meteorological Model'' dialog for this method is shown below: | ||
:[[Image:HMSSCSHypotheticalStorm2. | :[[Image:HMSSCSHypotheticalStorm2.png|thumb|none|left|500 px|''HMS Meteorological Model'' dialog for the "SCS Hypothetical Storm" method.]] | ||
== Related Topics: == | == Related Topics: == | ||
* [[WMS:HEC-HMS Gages|Gages]] | * [[WMS:HEC-HMS Gages|Gages]] | ||
* [[WMS:HEC-HMS Convert Grids|Convert Grids (NEXRAD Radar rainfall grids)]] | * [[WMS:HEC-HMS Convert Grids|Convert Grids (NEXRAD Radar rainfall grids)]] | ||
* [[WMS:HEC-HMS Job Control#Meteorological Options|Meteorological Options]] | * [[WMS:HEC-HMS Job Control#Meteorological Options|Meteorological Options]] | ||
* [[WMS:HEC-HMS|HMS Overview]] | * [[WMS:HEC-HMS|HMS Overview]] |
Latest revision as of 21:24, 12 December 2023
Define meteorologic data for the model by selecting the Meteorologic Parameters menu item from the HEC-HMS menu.
Selecting this menu item will bring up the HMS Meteorological Model dialog. This dialog is used to assign precipitation data to all the basins in the model.
The same precipitation method must be assigned to all the basins in the HMS model. The precipitation method chosen should be based on the type of analysis to be run. If having rainfall gage data for the watershed, use the user hyetograph or the user gage weighting method. If wanting to create a synthetic storm with a known exceedance probability, select the frequency storm method. If wanting to model a standard project storm, select the standard project storm or the SCS hypothetical storm method. Only use the No Precipitation option if the HMS model does not have any basins. See the topics below for more detailed information about the HMS Meteorological Model dialog.
HEC-HMS User Hyetograph
The User Hyetograph method can be used if a hyetograph is known for each sub-basin of the watershed being modeled. Get this hyetograph from recorded data or from any other method. Enter the same or different hyetographs for each basin, but each basin can only have a single hyetograph. Define the hyetograph by clicking on the XY Series button in the HMS Meteorological Model dialog shown below, and define the hyetograph in the XY series editor:
Standard Project Storm
"The standard project storm method can be used to compute precipitation for estimating the standard project flood (Corps of Engineers, 1952). The method is appropriate for watersheds in the United States east of 105° west longitude with an area less than 1,000 square miles. New methods in risk-based analysis have generally replaced the standard project flood criteria." (HEC-HMS User's Manual)
The HMS Meteorological Model dialog for the standard project storm method is shown below:
Get the index precipitation value (also known as the probable maximum index precipitation) from HYDROMET Report 33. It can also be estimated from plates contained in EM 1110-2-1411 (US Army Corps of Engineers) and represents the total precipitation depth for the storm. The storm area is the total drainage area at the point where the standard project flood is to be estimated. For the temporal distribution type, the standard storm distributes the precipitation according to the criteria outlined in EM 1110-2-1411. The "SWD" option distributes precipitation according to the Southwestern Division criteria (table 3.1 of the HEC-1 reference manual).
Each basin requires a transposition factor. The transposition factor for each sub-basin can range from 0.80 to 1.40 and is multiplied by the index precipitation to determine the mean areal precipitation. The transposition factor can be determined from the SPS isohyetal pattern contained in EM 1110-2-1411 and a map of the watershed.
Reference
USACE (1952) Standard project flood determinations. EM 1110-2-1411. Washington, DC.
Frequency Storm
"The frequency storm method can be used to create a balanced, synthetic storm with a known exceedance probability. Automatic adjustments for storm area and series type are based on the exceedance probability. Depth-duration data are usually obtained from publications such as TP-40 (National Weather Service, 1961)." (HEC-HMS User's Manual) The options for defining a frequency storm are shown below:
Follow the following steps (from the HEC-HMS User's Manual) to set up a frequency storm:
- Select a storm exceedance probability from the list (Exceedance probability = (1 / Return Period) * 100%).
- Set the series type for the desired output.
- Select the maximum intensity duration and the total storm duration.
- Enter the precipitation depths corresponding to the selected exceedance probability for the durations between the maximum intensity and storm durations.
- Select the percentage of the storm duration that occurs before the peak intensity.
- Enter the storm area. This is equal to the total drainage area at the point where the exceedance probability will be inferred for the computed flow.
SCS Hypothetical Storm
"The SCS hypothetical storm method implements the four synthetic rainfall distributions developed by the Natural Resources Conservation Service (NRCS) from observed precipitation events. Each distribution contains rainfall intensities arranged to maximize the peak runoff for a given total storm depth. The four distributions correspond to different geographic regions (Soil Conservation Service, 1986)." (HEC-HMS User's Manual)
The only data requirements for this method are the storm type and the storm depth. The storm depth can be determined for different areas of the United States by looking at the following map (Figure B-2 from Appendix B of the TR-55 manual).
This method does not perform any depth-area reductions. The HMS Meteorological Model dialog for this method is shown below:
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