Subsidence Overlay: Difference between revisions

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{{learned|what the Subsidence overlay is|what calculations are built into the subsidence overlay|what information is displayed by the subsidence overlay|how to configure the subsidence overlay}}
{{learned|what the Subsidence overlay is|what calculations are built into the subsidence overlay|what information is displayed by the subsidence overlay|how to configure the subsidence overlay}}
''Ground water (Overlay) redirects here, because they perform the same calculations.''


==What is the subsidence overlay==
==What is the subsidence overlay==
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[[File:Subsidence-Overlay.jpg|thumb|420px|left|The subsidence overlay]]
[[File:Subsidence-Overlay.jpg|thumb|420px|left|The subsidence overlay]]


The subsidence overlay is a [[grid overlay]], and part of the [[subsidence calculation|subsidence collection]] of overlays. It shows which places in the [[3D world]] are subject to subsidence due to oxidation and/or compaction of peat.
The subsidence overlay is a [[grid overlay]], and part of the [[subsidence calculation|subsidence collection]] of overlays. It shows which places in the [[3D world]] are subject to subsidence due to oxidation and/or compaction of peat. There are actually multiple overlays which perform the exact same calculations, but the output of which differ.


The subsidence overlay can be used to calculate the amount of subsidence which takes place on peat soil, specifically due to peat oxidation and compaction. In reality, there are more factors which can compound subsidence but these are not yet part of this set of calculations. The calculations are also specific for peat soil. Separate formulas for other soil types have not yet been implemented. This means that results have a greater margin of error for different use-cases.<br style='clear:left;'>
The subsidence overlay can be used to calculate the amount of subsidence which takes place on peat soil, specifically due to peat oxidation and compaction. In reality, there are more factors which can compound subsidence but these are not yet part of this set of calculations. The calculations are also specific for peat soil. Separate formulas for other soil types have not yet been implemented. This means that results have a greater margin of error for different use-cases.<br style='clear:left;'>

Revision as of 11:15, 25 July 2017

Template:Learned

Ground water (Overlay) redirects here, because they perform the same calculations.

What is the subsidence overlay

The subsidence overlay

The subsidence overlay is a grid overlay, and part of the subsidence collection of overlays. It shows which places in the 3D world are subject to subsidence due to oxidation and/or compaction of peat. There are actually multiple overlays which perform the exact same calculations, but the output of which differ.

The subsidence overlay can be used to calculate the amount of subsidence which takes place on peat soil, specifically due to peat oxidation and compaction. In reality, there are more factors which can compound subsidence but these are not yet part of this set of calculations. The calculations are also specific for peat soil. Separate formulas for other soil types have not yet been implemented. This means that results have a greater margin of error for different use-cases.

How the overlay calculates

Subsidence is currently composed of 2 forms of reduction of peat: oxidation and compaction. These forms of subsidence are both relevant for the complete picture of subsidence, but are, in principle, calculated via separate formulas. The results of these formulas are added together to get the total amount of subsidence.

Oxidation

Peat, when exposed to oxygen, can oxidize. In this process the peat combines with the air to form CO2, reducing the total mass and volume of the peat. The amount of oxidation depends on the clay thickness, because clay may insulate the peat, preventing it from oxidizing. It also depends on the (lowest) ground water level in relation to the surface of the land.

For information on the exact calculation of subsidence due to oxidation, see the article on Subsidence calculation (section on Oxidation).

Ground water levels

Ground water levels strongly affect how much peat can oxidize. Ground water levels, in turn, are affected by surface water levels, which can be changed during a session. Based on changes in surface water level, the ground water level changes as well.

For information on the exact calculation of ground water level changes, see the article on Subsidence Calculation (section on Ground Water ).

Compaction

Peat is a porous and relatively soft terrain type, meaning it can be compressed. Based on the amount of peat in the ground, the density of the top layer, and the net height increase.

For information on the exact calculation of subsidence due to compaction, see the article on Subsidence calculation (section on Compaction).

Multi-year calculations

Subsidence is calculated in 1-year steps. For each year, the amount of subsidence is calculated. That amount is then used to recalculate the input parameters for the overlay. The next 1-year step is then calculated.

Output

The output of all subsidence overlays is in meters. Depending on the exact overlay added to the project, the output is the amount of subsidence as the result of one specific calculation, or the sum of all the calculations of subsidence.

The results can be exported as GeoTiff.

Hover Panel

The hover panel will display the following information:

  • The amount of subsidence taking place over the configured amount of years.
  • The current surface water level, and to what level is will have changed after the subsidence has taken place.
  • The indexation policy currently configured for this water level area.

Affecting the overlay

During a session, stakeholders can affect the data in the project. They can do this through, for example, actions or events. This can include affecting data which is used in the subsidence calculation. The subsidence overlay is then recalculated with that new data.

Oxidation

Oxidation is affected by changes in the water level. During a session, if the WATER_LEVEL attribute is changed, the ground water level is adjusted as well. This in turn leads to more or less subsidence through oxidation. The ground water level can also be affected by the user creating drainage. These are constructions with a "drainage" function value. Drainage sets the ground water level to an artificial height, affecting the amount of oxidation taking place.

Compaction

During a session, a stakeholder can raise or lower land. They can do this directly, via land sculpting actions, or by constructing dikes. As the land is raised above the starting height, more compaction will start taking place.

Configuring the overlay

When the subsidence overlay is added to a project, there is some minimum information required for a calculation.

Peat soil

The calculation will only work when the terrain is sensitive to subsidence. By default, peat is the only terrain sensitive to subsidence. If your project does not yet have a peat soil, you can either set a different soil type to be sensitive to subsidence, or add peat to your project.

Template:Editor ribbon

How to change soil sensitivity to subsidence:
  1. Hover over the 3D world and click to find the underground soil type
  2. Select that underground soil type in the left panel
  3. In the right panel, switch to the attributes tab
  4. Add the attribute "SUBSIDENCE" with value 1
How to change the soil type:
  1. Select "peat" in the left panel
  2. Select the "General" tab in the right panel
  3. Draw the terrain in the 3D world

Water level areas

Subsidence is only calculated within water level areas, regardless of what data is present in the project. These areas are defined by the fact that they have a WATER_LEVEL attribute.

There are 2 ways of getting this data into your project: by importing it (i.e. your own data) into the project as areas with attributes, or by manually drawing the appropriate areas and adding attributes to those.

Template:Editor ribbon

How to import water level areas:
  1. Drag your GeoJSON file into the editor
  2. Select "Import as areas
  3. Rename the water level attribute to "WATER_LEVEL"
  4. Select "Send"
How to create a water level area manually:
  1. Add a new area to the project
  2. Draw the area into the 3D World
  3. Add the attribute "WATER_LEVEL" to the area, with a value of, for example, "-10"
  4. Select "refresh grid"

Refresh overlays

When data has been loaded in or changed in the editor, the grid is not updated automatically, so you will not immediately see your changes. To force the grid to update, you can refresh the grid.

Note that only oxidation is calculated outside of a session or testrun. Compaction requires a stakeholder to take a certain type of action first.

Further data

It's possible to configure the overlay further with additional data.

Ground water levels

By default, the ground water levels are loaded in from a publicly available geotiff automatically. Under the "Keys" tab in the right panel, you can change the selected geotiff by selecting a different one at "Include Ground Water Tiff". You can also disable the ground water geotiff, and use a ground water level attribute of areas instead.

How to add your own ground water data:
  1. Select the overlay
  2. In the right panel, select the "keys" tab
  3. Uncheck the "Include Ground Water Tiff" checkbox
  4. Select or create an area, part of the 3D world
  5. Add the attribute "GLG" to the area, with a value of, for example, "-1"

Clay thickness

By default, no data about clay thickness is available, and is considered to be "0". It's possible to add this attribute to areas to further influence the amount of subsidence taking place.

How to add clay thickness data:
  1. Select the overlay
  2. Select or create an area, part of the 3D world
  3. Add the attribute "CLAY_THICKNESS" to the area, with a value of, for example, "0,4"

Other keys/attributes

For more information on which values can be adjusted, see Subsidence calculation.