GMS:ETS Package: Difference between revisions

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{{Version GMS 7.0}}
{{MODFLOW Links}}
{{MODFLOW Links}}


The ETS package is an enhancement of the [[GMS:EVT Package|EVT]] package and "allows simulation of evapotranspiration with a user-defined relation between evapotranspiration rate and hydraulic head."<ref name="ofr00-466">{{citation  
The EvapoTranspiration Segments (ETS) Package is an enhancement of the [[GMS:EVT Package|EVT]] package and "allows simulation of evapotranspiration with a user-defined relation between evapotranspiration rate and hydraulic head."<ref name="ofr00-466">{{citation  
|last=Banta
|last=Banta
|first=Edward R.
|first=Edward R.
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|place=Denver, Colorado
|place=Denver, Colorado
|year=2000
|year=2000
|url=http://water.usgs.gov/nrp/gwsoftware/modflow2000/ofr00-466.pdf
|url=http://water.usgs.gov/nrp/gwsoftware/modflow2000/ofr00-466.pdf
}}</ref> It is included in MODFLOW 2000 and GMS includes an interface to it starting at version 7.0.
}}</ref> It is included in MODFLOW 2000 and GMS includes an interface to it starting at version 7.0.
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==Evapotranspiration Segments==
==Evapotranspiration Segments==
[[File:MODFLOW-ETS.jpg|thumb|350 px|The ''MODFLOW ETS Package'' dialog.]]
From the package documentation:
From the package documentation:
<blockquote style="margin-top:0px; margin-bottom:0px;">In the ETS1 Package, the functional relation of evapotranspiration rate to head is conceptualized as a segmented line in the variable interval. The segments that determine the shape of the function in the variable interval are defined by intermediate points where adjacent segments join. The ends of the segments at the top and bottom of the variable interval are defined by the ET surface, the maximum evapotranspiration rate, and the extinction depth. The number of intermediate points that must be defined is one less than the number of segments in the variable interval. For each intermediate point, two values, PXDP and PETM, are entered to define the point. PXDP is a proportion (between zero and one) of the extinction depth, and PETM is a proportion of the maximum evapotranspiration rate. PXDP is 0.0 at the ET surface and is 1.0 at the bottom of the variable interval. PETM is 1.0 at the ET surface and is 0.0 at the bottom of the variable interval. Segments are numbered such that segment one is the segment with its upper endpoint at the ET surface, and segment numbers increase downward. The relation of evapotranspiration rate to head is defined over the model grid by a series of two-dimensional arrays; therefore, PXDP and PETM also are specified as arrays.<ref name="ofr00-466"/></blockquote>
The input order of the arrays defining the segmented line is important and is defined in the package documentation:
<blockquote style="margin-top:0px; margin-bottom:0px;">
PXDP is a proportion of the extinction depth (dimensionless), measured downward from the ET surface, which, with PETM, defines the shape of the relation between the evapotranspiration rate and head. The value of PXDP must be between 0.0 and 1.0, inclusive. Repetitions of PXDP and PETM are read in sequence such that the first occurrence represents the bottom of the first segment, and subsequent repetitions represent the bottom of successively lower segments. Accordingly, PXDP values for later repetitions (representing lower segments) should be greater than PXDP values for earlier repetitions.
PETM is a proportion of the maximum evapotranspiration rate (dimensionless) which, with PXDP, defines the shape of the relation between the evapotranspiration rate and head. The value of PETM should be between 0.0 and 1.0, inclusive. Repetitions of PXDP and PETM are read in sequence such that the first occurrence represents the bottom of the first segment, and subsequent repetitions represent the bottoms of successively lower segments. Accordingly, PETM values for later repetitions (representing lower segments) generally would be less than PETM values for earlier repetitions.<ref name="ofr00-466"/></blockquote>
===ETS Package Dialog===
The ''MODFLOW ETS Package'' dialog has the following options:
; ET Option : Three evapotranspiration options are supported by MODFLOW: "ET only at the top layer", "ET at specified vertical cells", and "ET at highest active cells".
; Multiplier : The multiplier is a constant which can be written to the package file with each stress period array. Each value in the array is scaled by the multiplier as the array is imported to MODFLOW. The format button brings up a dialog listing the standard MODFLOW formats. This format is used for displaying the values in the spreadsheet and it controls how the values are written to the package file.
; Stress Periods : The values displayed in the spreadsheet are for an individual stress period. The values associated with other stress periods can be edited by entering the ID of the desired stress period in the ''Stress period'' edit box in the center of the dialog. If the ''Use previous'' option is selected for a given stress period, the values from the previous stress period are used and the spreadsheet is dimmed.
; Layer Indicator : If the ET at specified vertical cells option is chosen, the layer indicator for each vertical cell can be displayed and edited in the spreadsheet window by selecting Layer indicator in the ''View/Edit'' option.
; Edit All Use Previous/Multipliers : This button brings up a spreadsheet allowing the user to edit the ''Use Previous values'' and the multipliers for the active array for each stress period.


<blockquote>In the ETS1 Package, the functional relation of evapotranspiration rate to head is conceptualized as a segmented line in the variable interval. The segments that determine the shape of the function in the variable interval are defined by intermediate points where adjacent segments join. The ends of the segments at the top and bottom of the variable interval are defined by the ET surface, the maximum evapotranspiration rate, and the extinction depth. The number of intermediate points that must be defined is one less than the number of segments in the variable interval. For each intermediate point, two values, PXDP and PETM, are entered to define the point. PXDP is a proportion (between zero and one) of the extinction depth, and PETM is a proportion of the maximum evapotranspiration rate. PXDP is 0.0 at the ET surface and is 1.0 at the bottom of the variable interval. PETM is 1.0 at the ET surface and is 0.0 at the bottom of the variable interval. Segments are numbered such that segment one is the segment with its upper endpoint at the ET surface, and segment numbers increase downward. The relation of evapotranspiration rate to head is defined over the model grid by a series of two-dimensional arrays; therefore, PXDP and PETM also are specified as arrays.<ref name="ofr00-466"/></blockquote>
; 2D Dataset &rarr; Array : The '''2D Dataset &rarr; Array''' button brings up the ''Data Browser'' listing all of the current datasets associated with the current 2D grid. In order for this button to be active, the 2D grid must have the same number of rows and columns as the 3D grid. The selected dataset is copied to the ET array. Datasets are typically generated with the 2D Scatter Point module. The 2D Scatter Point module can be used to interpolate from a scattered set of rainfall measurements to the cell locations. If the dataset is transient, the values in the dataset are linearly interpolated, if necessary, to each stress period as the dataset is copied to the array.


The input order of the arrays defining the segmented line is important and is defined in the package documentation:
; 3D Dataset &rarr; Array : For MODFLOW-USG and MODFLOW-USG Transport only. The '''3D Dataset &rarr; Array''' button brings up the ''Select Dataset'' listing all of the current datasets associated with the current 3D grid. In order for this button to be active, the 3D dataset must have the same number of rows and columns as the 3D grid. The selected dataset is copied to the ET array. Datasets are typically generated with the 3D Scatter Point module. The 3D Scatter Point module can be used to interpolate from a scattered set of rainfall measurements to the cell locations. If the dataset is transient, the values in the dataset are linearly interpolated, if necessary, to each stress period as the dataset is copied to the array.
 
; Array &rarr; 2D Dataset : The '''Array &rarr; 2D Dataset''' button copies the array to the 2D dataset list associated with the existing 2D grid or UGrid.
 
; Constant &rarr; Array : The '''Constant &rarr; Array''' button brings up a dialog which prompts for a single value. This constant is then assigned to each item in the array for the given stress period.
 
; Raster &rarr; Array : The '''Raster &rarr; Array''' button brings up a data browser listing all of the current rasters. Multiple rasters can be selected. After selecting the raster(s) to use, the ''Raster Stress Period Mapping'' dialog will appear. Each raster must be assigned to a stress period. By default, rasters are unassigned.
:If the raster resolution is higher than the grid where there are multiple raster pixels in a grid cell, the pixels will be averaged to get one value for the cell. If it is the other way around, then the grid cell gets the value from the raster pixel that the grid cell center is in. If the raster doesn't cover the whole grid, whatever array values were there before are left unchanged.


<blockquote>PXDP-is a proportion of the extinction depth (dimensionless), measured downward from the ET surface, which, with PETM, defines the shape of the relation between the evapotranspiration rate and head. The value of PXDP must be between 0.0 and 1.0, inclusive. Repetitions of PXDP and PETM are read in sequence such that the first occurrence represents the bottom of the first segment, and subsequent repetitions represent the bottom of successively lower segments. Accordingly, PXDP values for later repetitions (representing lower segments) should be greater than PXDP values for earlier repetitions.


PETM-is a proportion of the maximum evapotranspiration rate (dimensionless) which, with PXDP, defines the shape of the relation between the evapotranspiration rate and head. The value of PETM should be between 0.0 and 1.0, inclusive. Repetitions of PXDP and PETM are read in sequence such that the first occurrence represents the bottom of the first segment, and subsequent repetitions represent the bottoms of successively lower segments. Accordingly, PETM values for later repetitions (representing lower segments) generally would be less than PETM values for earlier repetitions.<ref name="ofr00-466"/></blockquote>
; Spreadsheet : The ET flux values for each of the vertical columns in the grid are displayed and edited in the spreadsheet at the lower part of the dialog.


==Segmented line functions in GMS==
==Segmented Line Functions in GMS==
In GMS, the ETS segmented line function can be defined in a conceptual model. When this is done, the standard [[XY Series Editor]] is used. The XY Series Editor is a simple tool for creating 2D curves. When used to define the ETS segmented function, the X values correspond to PXDP, and the Y values correspond to PETM. The order of the values is important and is defined by the package documentation as mentioned above. PXDP should be entered in order of increasing value, and PETM should be entered in order of decreasing value. Here are a couple of examples:
In GMS, the ETS segmented line function can be defined in a conceptual model. When this is done, the standard ''[[XY Series Editor]]'' is used. The ''XY Series Editor'' is a simple tool for creating 2D curves. When used to define the ETS segmented function, the X values correspond to PXDP, and the Y values correspond to PETM. The order of the values is important and is defined by the package documentation as mentioned above. PXDP should be entered in order of increasing value, and PETM should be entered in order of decreasing value. Here are a couple of examples:


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In a GMS conceptual model, it is not possible to define segmented lines which vary with time. However, this can be done in the ETS Package dialog.
In a GMS conceptual model, it is not possible to define segmented lines which vary with time. However, this can be done in the ''ETS Package'' dialog.


==Notes==
==Notes==
<references/>
{{reflist}}




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[[Category:MODFLOW]]
[[Category:MODFLOW]]
[[Category:MODFLOW Packages]]
[[Category:MODFLOW Packages]]
[[Category:MODFLOW Dialogs]]
[[Category:External Links]]

Latest revision as of 20:14, 5 March 2024

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UZF1

The EvapoTranspiration Segments (ETS) Package is an enhancement of the EVT package and "allows simulation of evapotranspiration with a user-defined relation between evapotranspiration rate and hydraulic head."[1] It is included in MODFLOW 2000 and GMS includes an interface to it starting at version 7.0.

From OFR00-466[1]

Evapotranspiration Segments

The MODFLOW ETS Package dialog.

From the package documentation:

In the ETS1 Package, the functional relation of evapotranspiration rate to head is conceptualized as a segmented line in the variable interval. The segments that determine the shape of the function in the variable interval are defined by intermediate points where adjacent segments join. The ends of the segments at the top and bottom of the variable interval are defined by the ET surface, the maximum evapotranspiration rate, and the extinction depth. The number of intermediate points that must be defined is one less than the number of segments in the variable interval. For each intermediate point, two values, PXDP and PETM, are entered to define the point. PXDP is a proportion (between zero and one) of the extinction depth, and PETM is a proportion of the maximum evapotranspiration rate. PXDP is 0.0 at the ET surface and is 1.0 at the bottom of the variable interval. PETM is 1.0 at the ET surface and is 0.0 at the bottom of the variable interval. Segments are numbered such that segment one is the segment with its upper endpoint at the ET surface, and segment numbers increase downward. The relation of evapotranspiration rate to head is defined over the model grid by a series of two-dimensional arrays; therefore, PXDP and PETM also are specified as arrays.[1]

The input order of the arrays defining the segmented line is important and is defined in the package documentation:

PXDP is a proportion of the extinction depth (dimensionless), measured downward from the ET surface, which, with PETM, defines the shape of the relation between the evapotranspiration rate and head. The value of PXDP must be between 0.0 and 1.0, inclusive. Repetitions of PXDP and PETM are read in sequence such that the first occurrence represents the bottom of the first segment, and subsequent repetitions represent the bottom of successively lower segments. Accordingly, PXDP values for later repetitions (representing lower segments) should be greater than PXDP values for earlier repetitions.

PETM is a proportion of the maximum evapotranspiration rate (dimensionless) which, with PXDP, defines the shape of the relation between the evapotranspiration rate and head. The value of PETM should be between 0.0 and 1.0, inclusive. Repetitions of PXDP and PETM are read in sequence such that the first occurrence represents the bottom of the first segment, and subsequent repetitions represent the bottoms of successively lower segments. Accordingly, PETM values for later repetitions (representing lower segments) generally would be less than PETM values for earlier repetitions.[1]

ETS Package Dialog

The MODFLOW ETS Package dialog has the following options:

ET Option
Three evapotranspiration options are supported by MODFLOW: "ET only at the top layer", "ET at specified vertical cells", and "ET at highest active cells".
Multiplier
The multiplier is a constant which can be written to the package file with each stress period array. Each value in the array is scaled by the multiplier as the array is imported to MODFLOW. The format button brings up a dialog listing the standard MODFLOW formats. This format is used for displaying the values in the spreadsheet and it controls how the values are written to the package file.
Stress Periods
The values displayed in the spreadsheet are for an individual stress period. The values associated with other stress periods can be edited by entering the ID of the desired stress period in the Stress period edit box in the center of the dialog. If the Use previous option is selected for a given stress period, the values from the previous stress period are used and the spreadsheet is dimmed.
Layer Indicator
If the ET at specified vertical cells option is chosen, the layer indicator for each vertical cell can be displayed and edited in the spreadsheet window by selecting Layer indicator in the View/Edit option.
Edit All Use Previous/Multipliers
This button brings up a spreadsheet allowing the user to edit the Use Previous values and the multipliers for the active array for each stress period.
2D Dataset → Array
The 2D Dataset → Array button brings up the Data Browser listing all of the current datasets associated with the current 2D grid. In order for this button to be active, the 2D grid must have the same number of rows and columns as the 3D grid. The selected dataset is copied to the ET array. Datasets are typically generated with the 2D Scatter Point module. The 2D Scatter Point module can be used to interpolate from a scattered set of rainfall measurements to the cell locations. If the dataset is transient, the values in the dataset are linearly interpolated, if necessary, to each stress period as the dataset is copied to the array.
3D Dataset → Array
For MODFLOW-USG and MODFLOW-USG Transport only. The 3D Dataset → Array button brings up the Select Dataset listing all of the current datasets associated with the current 3D grid. In order for this button to be active, the 3D dataset must have the same number of rows and columns as the 3D grid. The selected dataset is copied to the ET array. Datasets are typically generated with the 3D Scatter Point module. The 3D Scatter Point module can be used to interpolate from a scattered set of rainfall measurements to the cell locations. If the dataset is transient, the values in the dataset are linearly interpolated, if necessary, to each stress period as the dataset is copied to the array.
Array → 2D Dataset
The Array → 2D Dataset button copies the array to the 2D dataset list associated with the existing 2D grid or UGrid.
Constant → Array
The Constant → Array button brings up a dialog which prompts for a single value. This constant is then assigned to each item in the array for the given stress period.
Raster → Array
The Raster → Array button brings up a data browser listing all of the current rasters. Multiple rasters can be selected. After selecting the raster(s) to use, the Raster Stress Period Mapping dialog will appear. Each raster must be assigned to a stress period. By default, rasters are unassigned.
If the raster resolution is higher than the grid where there are multiple raster pixels in a grid cell, the pixels will be averaged to get one value for the cell. If it is the other way around, then the grid cell gets the value from the raster pixel that the grid cell center is in. If the raster doesn't cover the whole grid, whatever array values were there before are left unchanged.


Spreadsheet
The ET flux values for each of the vertical columns in the grid are displayed and edited in the spreadsheet at the lower part of the dialog.

Segmented Line Functions in GMS

In GMS, the ETS segmented line function can be defined in a conceptual model. When this is done, the standard XY Series Editor is used. The XY Series Editor is a simple tool for creating 2D curves. When used to define the ETS segmented function, the X values correspond to PXDP, and the Y values correspond to PETM. The order of the values is important and is defined by the package documentation as mentioned above. PXDP should be entered in order of increasing value, and PETM should be entered in order of decreasing value. Here are a couple of examples:

Values Plot
Curve 1
PXDP PETM
0.0 1.0
0.25 0.25
1.0 0.0
XY Series Curve 1 for ETS
Curve 2
PXDP PETM
0.0 1.0
0.25 0.25
1.0 0.0
XY Series Curve 2 for ETS

In a GMS conceptual model, it is not possible to define segmented lines which vary with time. However, this can be done in the ETS Package dialog.

Notes