.. only:: html
Interpolation
=============
.. only:: html
.. contents::
:local:
:depth: 1
.. _qgisheatmapkerneldensityestimation:
Heatmap (kernel density estimation)
-----------------------------------
Creates a density (heatmap) raster of an input point vector layer using kernel
density estimation.
The density is calculated based on the number of points in a location, with larger
numbers of clustered points resulting in larger values. Heatmaps allow easy identification
of *hotspots* and clustering of points.
Parameters
..........
.. list-table::
:header-rows: 1
:widths: 20 20 20 40
:stub-columns: 0
* - Label
- Name
- Type
- Description
* - **Point layer**
- ``INPUT``
- [vector: point]
- Point vector layer to use for the heatmap
* - **Radius**
- ``RADIUS``
- [number]
Default: 100.0
- Heatmap search radius (or kernel bandwidth) in map units.
The radius specifies the distance around a point at which the
influence of the point will be felt.
Larger values result in greater smoothing, but smaller values
may show finer details and variation in point density.
* - **Output raster size**
- ``PIXEL_SIZE``
- [number]
Default: 0.1
- Pixel size of the output raster layer in layer units.
In the GUI, the size can be specified by the number of rows
(``Number of rows``) / columns (``Number of columns``) **or**
the pixel size( ``Pixel Size X`` / ``Pixel Size Y``).
Increasing the number of rows or columns will decrease the cell
size and increase the file size of the output raster.
The values in ``Rows``, ``Columns``, ``Pixel Size X`` and
``Pixel Size Y`` will be updated simultaneously - doubling the
number of rows will double the number of columns, and the cell
size will be halved.
The extent of the output raster will remain the same
(approximately).
* - **Radius from field**
Optional
- ``RADIUS_FIELD``
- [tablefield: numeric]
- Sets the search radius for each feature from an attribute
field in the input layer.
* - **Weight from field**
Optional
- ``WEIGHT_FIELD``
- [tablefield: numeric]
- Allows input features to be weighted by an attribute field.
This can be used to increase the influence certain features
have on the resultant heatmap.
* - **Kernel shape**
- ``KERNEL``
- [enumeration]
Default: *0*
- Controls the rate at which the influence of a point decreases
as the distance from the point increases.
Different kernels decay at different rates, so a triweight
kernel gives features greater weight for distances closer to
the point then the Epanechnikov kernel does.
Consequently, triweight results in “sharper” hotspots and
Epanechnikov results in “smoother” hotspots.
There are many shapes available (please see the
`Wikipedia page `_
for further information):
* 0 --- Quartic
* 1 --- Triangular
* 2 --- Uniform
* 3 --- Triweight
* 4 --- Epanechnikov
* - **Decay ratio (Triangular kernels only)**
Optional
- ``DECAY``
- [number]
Default: *0.0*
- Can be used with Triangular kernels to further control
how heat from a feature decreases with distance from the
feature.
* A value of 0 (=minimum) indicates that the heat will
be concentrated in the center of the given radius and
completely extinguished at the edge.
* A value of 0.5 indicates that pixels at the edge of
the radius will be given half the heat as pixels at
the center of the search radius.
* A value of 1 means the heat is spread evenly over
the whole search radius circle.
(This is equivalent to the ‘Uniform’ kernel.)
* A value greater than 1 indicates that the heat is
higher towards the edge of the search radius than at
the center.
* - **Output value scaling**
- ``OUTPUT_VALUE``
- [enumeration]
Default: *Raw*
- Allow to change the values of the output heatmap raster.
One of:
* 0 --- Raw
* 1 --- Scaled
* - **Heatmap**
- ``OUTPUT``
- [raster]
Default: ``[Save to temporary file]``
- Specify the output raster layer with kernel density values.
One of:
* Save to a Temporary File
* Save to File...
The file encoding can also be changed here.
Outputs
.......
.. list-table::
:header-rows: 1
:widths: 20 20 20 40
:stub-columns: 0
* - Label
- Name
- Type
- Description
* - **Heatmap**
- ``OUTPUT``
- [raster]
- Raster layer with kernel density values
Example: Creating a Heatmap
...........................
For the following example, we will use the ``airports`` vector point layer from
the QGIS sample dataset (see :ref:`label_sampledata`). Another excellent QGIS
tutorial on making heatmaps can be found at `http://qgistutorials.com
`_.
In Figure_Heatmap_data_processing_, the airports of Alaska are shown.
.. _figure_heatmap_data_processing:
.. figure:: img/heatmap_start.png
:align: center
Airports of Alaska
#. Open the Heatmap algorithm from the Interpolation group
#. In the :guilabel:`Point layer` |selectString| field, select ``airports``
from the list of point layers loaded in the current project.
#. Change the :guilabel:`Radius` to ``1000000`` meters.
#. Change the :guilabel:`Pixel size X` to ``1000``. The :guilabel:`Pixel size Y`,
:guilabel:`Rows` and :guilabel:`Columns` will be automatically updated.
#. Click on :guilabel:`Run` to create and load the airports heatmap
(see Figure_Heatmap_created_processing_).
.. _figure_heatmap_settings_processing:
.. figure:: img/heatmap_dialog.png
:align: center
The Heatmap Dialog
QGIS will generate the heatmap and add the results to your map window. By default, the heatmap
is shaded in greyscale, with lighter areas showing higher concentrations of airports. The heatmap
can now be styled in QGIS to improve its appearance.
.. _figure_heatmap_created_processing:
.. figure:: img/heatmap_loaded_grey.png
:align: center
The heatmap after loading looks like a grey surface
#. Open the properties dialog of the ``heatmap_airports`` layer (select the layer
``heatmap_airports``, open the context menu with the right mouse button and select
:guilabel:`Properties`).
#. Select the :guilabel:`Symbology` tab.
#. Change the :guilabel:`Render type` |selectString| to 'Singleband pseudocolor'.
#. Select a suitable :guilabel:`Color map` |selectString|, for instance ``YlOrRed``.
#. Click the :guilabel:`Classify` button.
#. Press :guilabel:`OK` to update the layer.
The final result is shown in Figure_Heatmap_styled_processing_.
.. _figure_heatmap_styled_processing:
.. figure:: img/heatmap_loaded_colour.png
:align: center
Styled heatmap of airports of Alaska
.. _Wikipedia: https://en.wikipedia.org/wiki/Kernel_(statistics)#Kernel_functions_in_common_use
.. _qgisidwinterpolation:
IDW Interpolation
-----------------
Generates an Inverse Distance Weighted (IDW) interpolation of a point vector layer.
Sample points are weighted during interpolation such that the influence of one point
relative to another declines with distance from the unknown point you want to create.
The IDW interpolation method also has some disadvantages: the quality of the interpolation
result can decrease, if the distribution of sample data points is uneven.
Furthermore, maximum and minimum values in the interpolated surface can only occur
at sample data points.
Parameters
..........
.. list-table::
:header-rows: 1
:widths: 20 20 20 40
:stub-columns: 0
* - Label
- Name
- Type
- Description
* - **Input layer(s)**
- ``INTERPOLATION_DATA``
- [string]
- Vector layer(s) and field(s) to use for the interpolation, coded
in a string (see the ``ParameterInterpolationData`` class in
:source:`InterpolationWidgets `
for more details).
The following GUI elements are provided to compose the
interpolation data string:
* **Vector layer** [vector: any]
* **Interpolation attribute** [tablefield: numeric]:
Attribute to use in the interpolation
* **Use Z-coordinate for interpolation** [boolean]:
Uses the layer's stored Z values (Default: False)
For each of the added layer-field combinations, a type can
be chosen:
* :guilabel:`Points`
* :guilabel:`Structured lines`
* :guilabel:`Break lines`
In the string, the layer-field elements are separated by
``'::|::'``.
The sub-elements of the layer-field elements are separated by
``'::~::'``.
* - **Distance coefficient P**
- ``DISTANCE_COEFFICIENT``
- [number]
Default: 2.0
- Sets the distance coefficient for the interpolation.
Minimum: 0.0, maximum: 100.0.
* - **Extent (xmin, xmax, ymin, ymax)**
- ``EXTENT``
- [extent]
- Extent of the output raster layer.
You have to declare the output extent by either choosing it from
the map canvas, selecting it from another layer or type it
manually.
* - **Output raster size**
- ``PIXEL_SIZE``
- [number]
Default: 0.1
- Pixel size of the output raster layer in layer units.
In the GUI, the size can be specified by the number of rows
(``Number of rows``) / columns (``Number of columns``) **or**
the pixel size( ``Pixel Size X`` / ``Pixel Size Y``).
Increasing the number of rows or columns will decrease the cell
size and increase the file size of the output raster.
The values in ``Rows``, ``Columns``, ``Pixel Size X`` and
``Pixel Size Y`` will be updated simultaneously - doubling the
number of rows will double the number of columns, and the cell
size will be halved.
The extent of the output raster will remain the same
(approximately).
* - **Interpolated**
- ``OUTPUT``
- [raster]
Default: ``[Save to temporary file]``
- Raster layer of interpolated values.
One of:
* Save to a Temporary File
* Save to File...
The file encoding can also be changed here.
Outputs
.......
.. list-table::
:header-rows: 1
:widths: 20 20 20 40
:stub-columns: 0
* - Label
- Name
- Type
- Description
* - **Interpolated**
- ``OUTPUT``
- [raster]
- Raster layer of interpolated values
.. _qgistininterpolation:
TIN Interpolation
-----------------
Generates a Triangulated Irregular Network (TIN) interpolation of a point vector layer.
With the TIN method you can create a surface formed by triangles of nearest neighbor
points. To do this, circumcircles around selected sample points are created and
their intersections are connected to a network of non overlapping and as compact
as possible triangles. The resulting surfaces are not smooth.
The algorithm creates both the raster layer of the interpolated values and the
vector line layer with the triangulation boundaries.
Parameters
..........
.. list-table::
:header-rows: 1
:widths: 20 20 20 40
:stub-columns: 0
* - Label
- Name
- Type
- Description
* - **Input layer(s)**
- ``INTERPOLATION_DATA``
- [string]
- Vector layer(s) and field(s) to use for the interpolation, coded
in a string (see the ``ParameterInterpolationData`` class in
:source:`InterpolationWidgets `
for more details).
The following GUI elements are provided to compose the
interpolation data string:
* **Vector layer** [vector: any]
* **Interpolation attribute** [tablefield: numeric]:
Attribute to use in the interpolation
* **Use Z-coordinate for interpolation** [boolean]:
Uses the layer's stored Z values (Default: False)
For each of the added layer-field combinations, a type can
be chosen:
* :guilabel:`Points`
* :guilabel:`Structured lines`
* :guilabel:`Break lines`
In the string, the layer-field elements are separated by
``'::|::'``.
The sub-elements of the layer-field elements are separated by
``'::~::'``.
* - **Interpolation method**
- ``METHOD``
- [enumeration]
Default: 0
- Set the interpolation method to be used. One of:
* :guilabel:`Linear`
* :guilabel:`Clough-Toucher (cubic)`
* - **Extent (xmin, xmax, ymin, ymax)**
- ``EXTENT``
- [extent]
- Extent of the output raster layer.
You have to declare the output extent by either choosing it from
the map canvas, selecting it from another layer or type it
manually.
* - **Output raster size**
- ``PIXEL_SIZE``
- [number]
Default: 0.1
- Pixel size of the output raster layer in layer units.
In the GUI, the size can be specified by the number of rows
(``Number of rows``) / columns (``Number of columns``) **or**
the pixel size( ``Pixel Size X`` / ``Pixel Size Y``).
Increasing the number of rows or columns will decrease the cell
size and increase the file size of the output raster.
The values in ``Rows``, ``Columns``, ``Pixel Size X`` and
``Pixel Size Y`` will be updated simultaneously - doubling the
number of rows will double the number of columns, and the cell
size will be halved.
The extent of the output raster will remain the same
(approximately).
* - **Interpolated**
- ``OUTPUT``
- [raster]
Default: ``[Save to temporary file]``
- The output TIN interpolation as a raster layer. One of:
* Save to a Temporary File
* Save to File...
The file encoding can also be changed here.
* - **Triangulation**
- ``TRIANGULATION``
- [vector: line]
Default: ``[Skip output]``
- The output TIN as a vector layer. One of:
* Skip Output
* Create Temporary Layer (``TEMPORARY_OUTPUT``)
* Save to File...
* Save to Geopackage...
* Save to PostGIS Table
Outputs
.......
.. list-table::
:header-rows: 1
:widths: 20 20 20 40
:stub-columns: 0
* - Label
- Name
- Type
- Description
* - **Interpolated**
- ``OUTPUT``
- [raster]
- The output TIN interpolation as a raster layer
* - **Triangulation**
- ``TRIANGULATION``
- [vector: line]
- The output TIN as a vector layer.
.. Substitutions definitions - AVOID EDITING PAST THIS LINE
This will be automatically updated by the find_set_subst.py script.
If you need to create a new substitution manually,
please add it also to the substitutions.txt file in the
source folder.
.. |selectString| image:: /static/common/selectstring.png
:width: 2.5em
.. |signMinus| image:: /static/common/symbologyRemove.png
:width: 1.5em
.. |signPlus| image:: /static/common/symbologyAdd.png
:width: 1.5em