Rainfall Overlay tutorial: Difference between revisions

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{{old references}}
==Getting Started==
==Getting Started==
# [//tygronsupport.freshdesk.com/support/tickets/new Contact Tygron Support] to request the Kockengen Tutorial project
# [//tygronsupport.freshdesk.com/support/tickets/new Contact Tygron Support] to request the Kockengen Tutorial project
# Open the {{software}}, logon with your user name and password and open the project ''Kockengen Tutorial''
# Open the {{software}}, logon with your user name and password and open the project ''Kockengen Tutorial''
# Download and unpack the content of this zip-file on your desktop: [http://support.tygron.com/w/downloads/tutorial/kockengen_data.zip]
# Download and unpack the content of this zip-file on your desktop: [http://downloads.support.tygron.com/tutorials/kockengen_data.zip]


Open the {{software}} and start the project Kockengen Tutorial. The project will appear:
Open the {{software}} and start the project Kockengen Tutorial. The project will appear:
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* sewerdistricts.geojson
* sewerdistricts.geojson
* weirs.geojson
* weirs.geojson
* overflows.geojson
* overflow.geojson
Some tips for using vector data files for the [[Water_Overlay]]:
Some tips for using vector data files for the [[Water_Overlay]]:
* All files need to have a coordinate reference system (CRS) defined, for the {{software}} to place the data on the correct location.
* All files need to have a coordinate reference system (CRS) defined, for the {{software}} to place the data on the correct location.
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Press Next to proceed to the Weather panel, here the user can define rainfall and evaporation input. Select the Option 'Linear' for rainfall over time. Change all numbers according to this picture:
Press Next to proceed to the Weather panel, here the user can define rainfall and evaporation input. Select the Option 'Linear' for rainfall over time. Change all numbers according to this picture:


[[File:Kockengen_figure05.PNG|500px]]
[[File:Kockengen_tutorial_rain_event.JPG|500px]]


By this setting you have defined a rainfall event:
By this setting you have defined a rainfall event:
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====Step 2.1: adding water level areas====  
====Step 2.1: adding water level areas====  
Press next to the screen for importing water areas. A [[Water_level_area_(Water_Overlay)|water level area]] is an area with a spatially uniform water level varying in time. Variation is caused by rainfall + evaporation on the surface water, inflow from sewer areas, inflow from the surface and groundwater inflow. [[File:Kockengen_figure06.PNG|thumb|250px|right]] [[File:Kockengen_figure07.PNG|thumb|250px|right]]
Press next to the screen for importing water areas. A [[Water_level_area_(Water_Overlay)|water level area]] is an area with a spatially uniform water level varying in time. Variation is caused by rainfall + evaporation on the surface water, inflow from sewer areas and inflow from the surface.
There are three options to define your water system:
[[File:Kockengen_figure06.PNG|thumb|250px|right]] [[File:Kockengen_tutorial_waterlevel_areas.JPG|thumb|250px|right]]
* Do Nothing: the surface water system effectively has infinite storage
There are several options to define your water system:
* Do Nothing: the surface water system effectively has storage based on the terrain height. 
* Import Water Areas: allows you to import a set of water level areas
* Import Water Areas: allows you to import a set of water level areas
* Generate Water Areas: allows you to define 1 water level area for your project area
* Generate Water Areas: allows you to define 1 water level area for your project area
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# An overview of your areas is generated; see right-side pictures. Press Next
# An overview of your areas is generated; see right-side pictures. Press Next
# In the next step you can filter features based on an existing attribute. We skip this step (because we do not want the filter our dataset) by pressing Next  
# In the next step you can filter features based on an existing attribute. We skip this step (because we do not want the filter our dataset) by pressing Next  
# We assign names to the water level areas using the NAME attribute from the geojson; ; see right-side pictures. Press Next  
# We assign names to the water level areas using the NAME attribute from the geojson; see right-side pictures. Press Next  
# We select all attributes, importing all attribute data from the geojson, and press Next. Note that only numerical attributes can be imported to the {{software}}.  
# We select all attributes, importing all attribute data from the geojson, and press Next. Note that only numerical attributes can be imported in to the {{software}}.  
# We assign the WATERLEVEL attribute of the GeoJSON to the WATER_LEVEL key of the overlay; see right-side pictures
# We assign the WATERLEVEL attribute of the GeoJSON to the WATER_LEVEL key of the overlay; see right-side pictures
# At Finalize we press Finish to upload the areas to the server
# At Finalize we press Finish to upload the areas to the server
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====Step 2.2: initial groundwater level====
====Step 2.2: initial groundwater level====
In step 2.2, you can specify ground water levels. By default, ground water levels are assumed to be the same as the water level in the water level area (see previous section). Alternatively, the user can specify pre-defined initial groundwater levels (GHG,GLG and GVG for the Netherlands) or a GeoTiff with ground water levels in meters below surface; see right-side pictures. For this example, choose the default option ('Do Nothing')[[File:Kockengen_figure08.PNG|thumb|250px|right]].
In step 2.2, you can specify ground water levels. Since this tutorial is about Rainfall, we choose the default option ('Do Nothing')[[File:Kockengen_tutorial_groundwater.JPG|thumb|250px|right]]; see right-side picture.


====Step 2.3: adding sewer areas====
====Step 2.3: adding sewer areas====
[[Sewer_area_(Water_Overlay)|Sewer districts]] are represented by areas which have one storage value [m], uniform in space. Sewer storage will vary in time by sewer inflow from connected buildings (buildings, roads, etc), pumped outflow to a WWTP (in the {{software}} this is to an external area outside of the project) and sewer overflow to surface water.
[[Sewer_area_(Water_Overlay)|Sewer districts]] are represented by areas which have one storage value [m], uniform in space. Sewer storage will vary in time by sewer inflow from connected buildings (buildings, roads, etc), pumped outflow to a WWTP (in the {{software}} this is to an external area outside of the project) and sewer overflow to surface water.
In the wizard there are several options for defining the sewer system:
* Do nothing: no sewer areas are defined, this means that there is no sewerage in the project
* Import sewers: import sewer data
* Generate sewers: let the {{software}} [[How_to_generate_a_sewer|generate sewer areas]], based on adjustable parameters
* Select existing sewers based on attribute: if you have already sewer areas imported, you can connect them by choosing a common attribute of the already imported data
Press import sewers and import the file sewerareas.geojson via the Geo data wizard. Assign the following attributes:
Press import sewers and import the file sewerareas.geojson via the Geo data wizard. Assign the following attributes:
* NAME: name of the sewer district
* NAME: name of the sewer district
* POC: pump capacity assigned to the sewer district [m3/s]
* POC: pump capacity assigned to the sewer district [m3/s]
* STORAGE: storage of the sewer district. [mm] [[File:Kockengen_figure09.PNG|thumb|250px|right]]
* STORAGE: storage of the sewer district. [mm] [[File:Kockengen_tutorial_sewer_attributes.JPG|thumb|250px|right]]
Follow the steps in the Geo Wizard according to the steps described in the water level areas section:
Follow the steps in the Geo Wizard according to the steps described in the water level areas section:
* At step 5, multiply the attribute value for STORAGE in the GeoJSON (mm) by 0,001 (conversion to m); see right-side pictures.  
* At step 5, multiply the attribute value for STORAGE in the GeoJSON (mm) by 0,001 (conversion to m); see right-side pictures.  
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====Step 2.4: adding inundation areas====
====Step 2.4: adding inundation areas====
[[Inundation_area_(Water_Overlay)|Inundation areas]] are used to represent inundated of flooded areas in advance of the model's simulation. In this Tutorial, choose the default option (''Do Nothing)''.
[[Inundation_area_(Water_Overlay)|Inundation areas]] are used to represent inundated of flooded areas in advance of the model's simulation. The following options are available:
* Do Nothing: there is no inundation area
* Import Water Areas: allows you to import inundation area(s)
* Generate Water Areas: allows you to define 1 inundation area for your project area
* Select existing water level areas based on attribute: allows you to connect already imported inundation data by using an existing attribute of this dataset
 
In this Tutorial, choose the default option (''Do Nothing)''.


====Step 2.5: adding hydraulic structures====
====Step 2.5: adding hydraulic structures====
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* WEIR_HEIGHT: the crest height [m + datum]; to be assigned to the WEIR_HEIGHT key  
* WEIR_HEIGHT: the crest height [m + datum]; to be assigned to the WEIR_HEIGHT key  
* WEIR_WIDTH: the width of the crest [m]; to be assigned to the WEIR_WIDTH key
* WEIR_WIDTH: the width of the crest [m]; to be assigned to the WEIR_WIDTH key
* WEIR_COEFF: tThe flow coefficient related to the shape of the weir; to be assigned to the WEIR_COEFFICIENT key
* WEIR_COEFF: tthe flow coefficient related to the shape of the weir; to be assigned to the WEIR_COEFFICIENT key
In the Geo Wizard follow the steps:
In the Geo Wizard follow the steps:
# Select Import a GeoJSON file and press Next. Press Select File and locate the wiers.geojson. Press Open and press Next.
# Select Import a GeoJSON file and press Next. Press Select File and locate the wiers.geojson. Press Open and press Next.
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====2.5.5 Adding Overflows====
====2.5.5 Adding Overflows====
You can upload the overflows.geojson by selecting Import Overflows in the Weirs screen. We will import overflows.geojson, using the following attributes:
You can upload the overflows.geojson by selecting Import Overflows in the Wizard. We will import overflow.geojson, using the following attributes:
* LEVEL: the crest level of the overflow; assign to the SEWER_OVERFLOW overlay key
* LEVEL: the crest level of the overflow; assign to the SEWER_OVERFLOW overlay key
* CAPACITY: the overflow capacity of the overflow; assign to the SEWER_OVERFLOW_SPEED overlay key
* CAPACITY: the overflow capacity of the overflow; assign to the SEWER_OVERFLOW_SPEED overlay key
Follow the Geo Data Wizard similar to the procedure at importing weirs (see 2.4.1 Adding Weirs) and view the result. What do the values mean?
Follow the Geo Data Wizard similar to the procedure at importing weirs (see 2.5.1 Adding Weirs) and view the result. What do the values mean?


[[File:Kockengen_figure13.PNG|500px]]
[[File:Kockengen_figure13.PNG|500px]]
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===Step 3: setup of coefficients===
===Step 3: setup of coefficients===
In this step you can adjust default parameters related to the surface (e.g. roughness), sub-surface (e.g. conductivity) and infrastructure (e.g. is a type connected to a sewer or not). As we work with a 3D world containing a lot of data, the determination of model-coefficients can be complex. E.g.:
In this step you can adjust default parameters related to the surface (e.g. roughness), sub-surface (e.g. conductivity) and infrastructure (e.g. is a type connected to a sewer or not). As we work with a 3D world containing a lot of data, the determination of model-coefficients can be complex. E.g.:
* A manning roughness coefficient can be related to the surface type (e.g. clay) if no infrastructure present. If infrastructure is present (e.g. a road), the value of the road will be used, and the value of the surface type will be ignored
* A [[Water_manning_(Water_Overlay)|manning roughness coefficient]] can be related to the surface type (e.g. clay) if no infrastructure present. If infrastructure is present (e.g. a road), the value of the road will be used, and the value of the surface type will be ignored
* An infiltration parameter can be related to the surface (land cover), infrastructure or underground (sub-surface). The minimum value of the three will be chosen as being representative for a cells infiltration rate.
* An infiltration parameter can be related to the surface (land cover), infrastructure or underground (sub-surface).
You can inspect the values by going to the pages. We will leave everything to default by pressing next (4x)
You can inspect the values by going to the pages. We will leave everything to default by pressing next (4x)


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===Step 4: Interactions===
===Step 4: Interactions===
The Rainfall Overlay can produce one or more results. By default Water Stress is chosen, which is the maximum water depth at simulation. For water cells a maximum allowed increase model parameter is set. Below that depth no water stress will be perceived.
Here you can choose to visualize your water system network in the rainfall overlay:
Here you can choose to visualize your water system network in the rainfall overlay:
* Display Water System network: shows the network of the water system
* Display Water System network: shows schematically the network of the water system  
* Display Weirs with Panels: shows all hydraulic structures, allowing the user to overwrite structure settings
* Display Weirs with Panels: shows on the location of weirs a panel, allowing the user to overwrite structure settings
* Display Water level Areas with Panels: shows all centroids of water level areas, allowing the user to overwrite initial water levels and outflow capacity
* Display Water level Areas with Panels: shows on all centroids of water level areas panels, allowing the user to overwrite initial water levels


[[File:Kockengen_figure15.PNG|500px]]
[[File:Kockengen_figure15.PNG|500px]]


===Step 5: Output Overlays===
===Step 5: Output Overlays===
The Rainfall Overlay can produce one or more results. By default Water Stress is chosen, which is the maximum water depth at simulation. For water cells a maximum allowed increase model parameter is set. Below that depth no water stress will be perceived.
The Rainfall Overlay can produce one or more results. By default the [[Waterstress_result_type_(Water_Overlay)|Water Stress]] is chosen, which is the amount of water on the surface. For water terrains a maximum allowed increase model parameter is set. Below that depth no water stress will be perceived. Also, the number of [[Timeframes_(Water_Overlay)|Timeframes]] can be selected with the slider. The more timeframes, the more intermediate steps there are recorded and viewable for the user. Note that timeframes are not the same as [[Timestep_formula_(Water_Overlay)|timesteps]].  
 
<br>
[[File:Kockengen_figure16.PNG|500px]]
[[File:Kockengen_figure16.PNG|500px]]


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==After completion of the wizard==
==After completion of the wizard==
After completing the wizard, you need to Refresh Grid to recalculate the inundation grid; every time you change a parameter the model will be recalculated if you press Refresh Grid.
[[File:Kockengen_tutorial_general_tab.JPG|thumb|150px|right|The general tab in the right panel]]
[[File:Kockengen_tutorial_inactive_copyJPG.JPG|thumb|150px|right|The inactive copy of the Rainfall overlay is greyed out]]
After finishing the wizard, you need to [[Grid_Overlay#Grid_recalculation|Update the grid]] to recalculate the rainfall overlay. Every time you change a parameter in the model, whether that is in the wizard or in the editor itself, the overlay has to be recalculated by pressing Update Now. However, if the [[Calculation_panel#Auto-update_indicators|auto update]] is on, the overlay is automatically recalculated when changing a parameter in the wizard. When working in/with a large project, a small grid size, long simulation time etc., it can be desirable to turn the auto update off in order to not have to wait every time on the recalculation of the overlay, until you are done with editing and ready for the results. When dealing with very long calculations, take note of the [[Peak_hours|peak hours]], the option to [[Calculation_panel#GPU_overview|cancel]] the calculation (if you notice that it will take a long time) and the option to [[Grid_Overlay#Delayed_calculation|delay]] the calculation.


When finished, please explore the following interesting features:
When finished, please explore the following interesting features:
* In the General Tab you can Download a Water Balance XLSX-file. Please explore
* In the General Tab you can show the [[Results (Water Overlay)#Water balance|Water Balance]]. Please explore
* Below there is a summary. Interesting features are the water balance summary and the Max Courant number.
* Below there is a summary, the [[Results (Water Overlay)#Debug info|debug info]], with among others the amount of timesteps.  
* In the General Tab, you can specify a 'Calculation Preference'. The preference 'accuracy' will respect a Courant number <1 until a maximum flow velocity of 10m/s, this flow velocity will be halved by specifying the preference 'average' (max 5m/s) and again if specified 'speed' (2.5m/s). Please try different options, evaluate the max courant number and computation times. Can you explain their relation?
* In the General Tab, you can specify the [[Calculation_preference_formula_(Water_Overlay)|Calculation Preferences]]. While keeping the grid size the same, evaluate the amount of timesteps. See also the [[Timestep formula (Water Overlay)|timestep formula]] for more information.
* In the General Tab you can press Change Grid to change the grid cell size. Can you see the difference, and see the impact on the Courant number?
* In the General Tab you can press ''Change Grid'' to change the [[grid cell size]]. Can you see the difference, and see the impact on the timesteps and calculation time?
* In the General Tab you can export the result as a GeoTiff. Please do so and visualize your result in QGIS.
* In the General Tab you can [[Geo_Data#Export_raster_data|export the result]] as a [[GeoTiff]]. Please do so and visualize your result in a GIS, for example QGIS.
* Open the Configuration Wizard again. Select more and/or different result types. Can you display and interpret the results?
* In the General Tab, click on ''Save overlay result''. Notice what happens: an inactive copy of the result type is created in the overlay left panel. This [[Results (Water Overlay)#Storing_specific_overlay_result|inactive copy]] can be used to store results, from for example a specific rain event, and compare it later with another result type of another rain event.
* In the General Tab, [[Warning and recommendations (Water Overlay)|warnings]] may also appear, for example about the accuracy of the model in relation to the grid cell size.
* Create an overlay of the water level areas to provide more insight. Follow the (general) steps [[Geo_Data_tutorial#Create_an_overlay|in the Geo Data tutorial]] for creating an overlay of the already imported water level areas.  
* Open the Rainfall Wizard again. Select more and/or different result types and update the Rainfall overlay. Can you display and interpret the results?
 
{{Water Module buttons}}

Revision as of 07:54, 14 June 2019

Getting Started

  1. Contact Tygron Support to request the Kockengen Tutorial project
  2. Open the Tygron Platform, logon with your user name and password and open the project Kockengen Tutorial
  3. Download and unpack the content of this zip-file on your desktop: [1]

Open the Tygron Platform and start the project Kockengen Tutorial. The project will appear:

Kockengen figure01.PNG

Adding a Rainfall Overlay

Follow these steps below to add a Rainfall Overlay:

  1. Hover over the button Overlays, in the current situation tab and select Add Rainfall. The rainfall overlay is added to the Overlays in the left-side-panel. And in the overlay bar on the right side of the map: Kockengen figure02.PNG
  2. Select the Rainfall overlay in the left side panel and take a moment to familiarize yourself with the tabs in the right panel: General, Keys, Legend and Attributes
    • General contains the most common information necessary to interpret the rainfall overlay.
    • In Keys you can relate settings for the Rainfall overlay to attribute information stored in the 3D world.
    • Legend allows you to customize your legend
    • Attributes contains the general settings of the Rainfall overlay.
  3. Click on the Configuration Wizard button. With the Rainfall Wizard, you can configure your water system, this includes:
    • The setup of the weather boundary condition
    • Definition of the water system, including water level areas (peilgebieden) and sewer districts
    • Setting of hydrological parameters

The Rainfall Wizard

Kockengen figure03.PNG

With the Rainfall Overlay Wizard you can configure your water system, including surface water and sewer districts. In this part of the tutorial you need to have prepared the following GeoJSON-files:

  • waterlevelareas.geojson
  • sewerdistricts.geojson
  • weirs.geojson
  • overflow.geojson

Some tips for using vector data files for the Water_Overlay:

  • All files need to have a coordinate reference system (CRS) defined, for the Tygron Platform to place the data on the correct location.
  • Hydraulic structures (weirs, culverts, pumps and overflows) should be imported as polygons, but translated in the Tygron Platform to either work as point- or line based structures. Read here more about this difference.

Kockengen figure04.PNG

Step 1: defining the weather

Press Next to proceed to the Weather panel, here the user can define rainfall and evaporation input. Select the Option 'Linear' for rainfall over time. Change all numbers according to this picture:

Kockengen tutorial rain event.JPG

By this setting you have defined a rainfall event:

  • Uniform rainfall in 120 minutes
  • With a total rainfall amount of 50mm
  • With a dry period after rainfall of 120 minutes, so a total simulation time of 4 hours
  • Reference evapotranspiration will be assumed on 1.5mm/day

Step 2: setup of the water system

Press next to proceed to the introduction screen: Setup Water System. Here you can define your water system using the prepared GeoJSONS.

Kockengen figure05B.PNG

Step 2.1: adding water level areas

Press next to the screen for importing water areas. A water level area is an area with a spatially uniform water level varying in time. Variation is caused by rainfall + evaporation on the surface water, inflow from sewer areas and inflow from the surface.

Kockengen figure06.PNG
Kockengen tutorial waterlevel areas.JPG

There are several options to define your water system:

  • Do Nothing: the surface water system effectively has storage based on the terrain height.
  • Import Water Areas: allows you to import a set of water level areas
  • Generate Water Areas: allows you to define 1 water level area for your project area
  • Select existing water level areas based on attribute: allows you to connect already imported water level data by using an existing attribute of this dataset

Select Import Water Level Areas and press Import Water Level Areas. The Geo Data Wizard will open. We will import waterlevelareas.geojson. Use the following attributes in the GeoJSON file as attributes for the Rainfall Overlay:

  • WATERLEVEL: the initial Water Level in the water level area (m + datum)
  • NAME: the name of the water level area

Steps in the Geo Data Wizard:

  1. Select Import a GeoJSON file and press Next. Press Select File and locate the waterlevelareas.geojson. Press Open and press Next.
  2. An overview of your areas is generated; see right-side pictures. Press Next
  3. In the next step you can filter features based on an existing attribute. We skip this step (because we do not want the filter our dataset) by pressing Next
  4. We assign names to the water level areas using the NAME attribute from the geojson; see right-side pictures. Press Next
  5. We select all attributes, importing all attribute data from the geojson, and press Next. Note that only numerical attributes can be imported in to the Tygron Platform.
  6. We assign the WATERLEVEL attribute of the GeoJSON to the WATER_LEVEL key of the overlay; see right-side pictures
  7. At Finalize we press Finish to upload the areas to the server

After importing your water level areas you can review all parameters by opening the selection menu. Take some time to review the attribute values. What is the meaning?

Step 2.2: initial groundwater level

In step 2.2, you can specify ground water levels. Since this tutorial is about Rainfall, we choose the default option ('Do Nothing')

Kockengen tutorial groundwater.JPG

; see right-side picture.

Step 2.3: adding sewer areas

Sewer districts are represented by areas which have one storage value [m], uniform in space. Sewer storage will vary in time by sewer inflow from connected buildings (buildings, roads, etc), pumped outflow to a WWTP (in the Tygron Platform this is to an external area outside of the project) and sewer overflow to surface water. In the wizard there are several options for defining the sewer system:

  • Do nothing: no sewer areas are defined, this means that there is no sewerage in the project
  • Import sewers: import sewer data
  • Generate sewers: let the Tygron Platform generate sewer areas, based on adjustable parameters
  • Select existing sewers based on attribute: if you have already sewer areas imported, you can connect them by choosing a common attribute of the already imported data

Press import sewers and import the file sewerareas.geojson via the Geo data wizard. Assign the following attributes:

  • NAME: name of the sewer district
  • POC: pump capacity assigned to the sewer district [m3/s]
  • STORAGE: storage of the sewer district. [mm]
    Kockengen tutorial sewer attributes.JPG

Follow the steps in the Geo Wizard according to the steps described in the water level areas section:

  • At step 5, multiply the attribute value for STORAGE in the GeoJSON (mm) by 0,001 (conversion to m); see right-side pictures.
  • At step 6, assign the the STORAGE attribute to the SEWER_STORAGE key and the POC attribute to the SEWER_PUMP_SPEED key

Take some time to review the attribute values in the imported area Kockengen. What is the meaning?

Step 2.4: adding inundation areas

Inundation areas are used to represent inundated of flooded areas in advance of the model's simulation. The following options are available:

  • Do Nothing: there is no inundation area
  • Import Water Areas: allows you to import inundation area(s)
  • Generate Water Areas: allows you to define 1 inundation area for your project area
  • Select existing water level areas based on attribute: allows you to connect already imported inundation data by using an existing attribute of this dataset

In this Tutorial, choose the default option (Do Nothing).

Step 2.5: adding hydraulic structures

In the Rainfall wizard it is possible to import the following hydraulic structures:

2.5.1 Adding Weirs

You can upload weirs.geojson by selecting Import Weirs in the Weirs screen and pressing Import Weirs. We will import weirs.geojson, using the following attributes:

Kockengen figure10.PNG
  • NAME: the name of the weir
  • WEIR_HEIGHT: the crest height [m + datum]; to be assigned to the WEIR_HEIGHT key
  • WEIR_WIDTH: the width of the crest [m]; to be assigned to the WEIR_WIDTH key
  • WEIR_COEFF: tthe flow coefficient related to the shape of the weir; to be assigned to the WEIR_COEFFICIENT key

In the Geo Wizard follow the steps:

  1. Select Import a GeoJSON file and press Next. Press Select File and locate the wiers.geojson. Press Open and press Next.
  2. An overview of your areas is generated as below. Press Next
  3. In the next step you can filter features based on attribute filtering. We skip this step by pressing Next
  4. We assign names to the water level areas using the NAME attribute from the geojson and press Next
  5. We select all attributes, importing all attribute data from the geojson, and press Next
  6. We assign the WEIR_HEIGHT attribute of the GeoJSON to the WEIR_HEIGHT key of the overlay, the WEIR_WIDTH attribute of the GeoJSON to the WEIR_WIDTH key of the rainfall overlay and the WEIR_COEFF attribute of the GeoJSON to the WEIR_COEFFICIENT attribute of the rainfall overlay.
  7. At Finalize we press Finish to upload the areas to the server

Take some time to review the attribute values. What is the meaning?

Kockengen figure12.PNG

2.5.2 Adding Culverts & 2.5.3 Adding Pumps & 2.5.4 Adding Inlets

Similar to the import procedure of Weirs, you can add pumps, culverts and inlets. In this Tutorial, choose the default (Do Nothing).

2.5.5 Adding Overflows

You can upload the overflows.geojson by selecting Import Overflows in the Wizard. We will import overflow.geojson, using the following attributes:

  • LEVEL: the crest level of the overflow; assign to the SEWER_OVERFLOW overlay key
  • CAPACITY: the overflow capacity of the overflow; assign to the SEWER_OVERFLOW_SPEED overlay key

Follow the Geo Data Wizard similar to the procedure at importing weirs (see 2.5.1 Adding Weirs) and view the result. What do the values mean?

Kockengen figure13.PNG

Step 3: setup of coefficients

In this step you can adjust default parameters related to the surface (e.g. roughness), sub-surface (e.g. conductivity) and infrastructure (e.g. is a type connected to a sewer or not). As we work with a 3D world containing a lot of data, the determination of model-coefficients can be complex. E.g.:

  • A manning roughness coefficient can be related to the surface type (e.g. clay) if no infrastructure present. If infrastructure is present (e.g. a road), the value of the road will be used, and the value of the surface type will be ignored
  • An infiltration parameter can be related to the surface (land cover), infrastructure or underground (sub-surface).

You can inspect the values by going to the pages. We will leave everything to default by pressing next (4x)

Kockengen figure14.PNG

Step 4: Interactions

Here you can choose to visualize your water system network in the rainfall overlay:

  • Display Water System network: shows schematically the network of the water system
  • Display Weirs with Panels: shows on the location of weirs a panel, allowing the user to overwrite structure settings
  • Display Water level Areas with Panels: shows on all centroids of water level areas panels, allowing the user to overwrite initial water levels

Kockengen figure15.PNG

Step 5: Output Overlays

The Rainfall Overlay can produce one or more results. By default the Water Stress is chosen, which is the amount of water on the surface. For water terrains a maximum allowed increase model parameter is set. Below that depth no water stress will be perceived. Also, the number of Timeframes can be selected with the slider. The more timeframes, the more intermediate steps there are recorded and viewable for the user. Note that timeframes are not the same as timesteps.
Kockengen figure16.PNG

Step 6: Input Overlays

The Rainfall Overlay uses several input parameters to compute output. These input overlays can be visualized in the Input Overlays section. Select the manning roughness value [m/s^1/3]

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Press Finish to finalize the wizard

After completion of the wizard

The general tab in the right panel
The inactive copy of the Rainfall overlay is greyed out

After finishing the wizard, you need to Update the grid to recalculate the rainfall overlay. Every time you change a parameter in the model, whether that is in the wizard or in the editor itself, the overlay has to be recalculated by pressing Update Now. However, if the auto update is on, the overlay is automatically recalculated when changing a parameter in the wizard. When working in/with a large project, a small grid size, long simulation time etc., it can be desirable to turn the auto update off in order to not have to wait every time on the recalculation of the overlay, until you are done with editing and ready for the results. When dealing with very long calculations, take note of the peak hours, the option to cancel the calculation (if you notice that it will take a long time) and the option to delay the calculation.

When finished, please explore the following interesting features:

  • In the General Tab you can show the Water Balance. Please explore
  • Below there is a summary, the debug info, with among others the amount of timesteps.
  • In the General Tab, you can specify the Calculation Preferences. While keeping the grid size the same, evaluate the amount of timesteps. See also the timestep formula for more information.
  • In the General Tab you can press Change Grid to change the grid cell size. Can you see the difference, and see the impact on the timesteps and calculation time?
  • In the General Tab you can export the result as a GeoTiff. Please do so and visualize your result in a GIS, for example QGIS.
  • In the General Tab, click on Save overlay result. Notice what happens: an inactive copy of the result type is created in the overlay left panel. This inactive copy can be used to store results, from for example a specific rain event, and compare it later with another result type of another rain event.
  • In the General Tab, warnings may also appear, for example about the accuracy of the model in relation to the grid cell size.
  • Create an overlay of the water level areas to provide more insight. Follow the (general) steps in the Geo Data tutorial for creating an overlay of the already imported water level areas.
  • Open the Rainfall Wizard again. Select more and/or different result types and update the Rainfall overlay. Can you display and interpret the results?