Inference Overlay: Difference between revisions

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[[File:Treesmask.jpg|thumb|right|Trees detected with Inference Overlay.]]
[[File:Treesmask.jpg|thumb|right|Trees detected with Inference Overlay.]]
The AI Inference Overlay is a [[Grid Overlay]] which can spatially identify features using one or more Prequel Grids. Features are identified using a Convolution [[Neural Network]]. This Neural Network takes a subsection (window) of the input grid and either classifies or detects one or more objects in that window. The window of detection marches over the input grid with a [[Stride fraction (Inference Overlay)|configurable stride]].  
The AI Inference Overlay is a [[Grid Overlay]] which can spatially identify features using one or more Prequel Grids. Features are identified using a Convolution [[Neural Network]] that used a limited amount of proposal regions (RCNN). This Neural Network takes a subsection (window) of the input grid and either;
* [[Neural Network (Inference Overlay)#Supported Convolution Types|classifies]] the image as a whole
* [[Neural Network (Inference Overlay)#Supported Convolution Types|detect one or more features]] in that image.
 
It is not possible to run the convolution network on the grid as a whole. Therefore, a marching window strategy is applied instead, where the window is moved over the input grid with a [[Stride fraction (Inference Overlay)|configurable stride]]. This window takes the input values of one or more grids and puts these into tensors representing either floating point values or color channels (red, green and blue). Depending on the dataset used to train the neural network, the tensor values are normalized based on a particular value range. For example, a relative height input tensor for a foliage neural network trained on height data can be normalized using a range of 0 to 40 meters, when 40 meters is considered the largest tree height in the Netherlands.


==Foliage Example==
==Foliage Example==
[[File:inference_foliage_animated.gif|frame|right|Animation of inference with a moving window and Bounding Box detection.]]
[[File:inference_foliage_animated.gif|frame|right|Animation of inference with a moving window and Bounding Box detection and a [[Stride fraction (Inference Overlay)|stride fraction]] of 0.5.]]
Using a [[Satellite Overlay]] of 0.1m detail, foliage features can be identified using an [[Inference Overlay]] and enhanced with a [[Digital Terrain Model Overlay]] (DTM), a [[WCS Overlay|WCS Overlay]] representing the [[DSM]], [[Combo Overlay]] to combine these and an optionally an iterative [[Avg & interpolation (overlay)|Max Overlay]] to enhance the foliage height. For more information, see this [[How to detect foliage using an Inference Overlay|how-to]].
Using a [[Satellite Overlay]] of 0.1m detail, foliage features can be identified using an [[Inference Overlay]] and enhanced with a [[Digital Terrain Model Overlay]] (DTM), a [[WCS Overlay|WCS Overlay]] representing the [[DSM]], [[Combo Overlay]] to combine these and an optionally an iterative [[Avg & interpolation (overlay)|Max Overlay]] to enhance the foliage height. For more information, see this [[How to detect foliage using an Inference Overlay|how-to]].
<gallery widths="200">
<gallery widths="200">
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|howtos=
|howtos=
* [[How to detect foliage using an Inference Overlay]]
* [[How to detect foliage using an Inference Overlay]]
* [[How to create foliage height areas based on an Inference Overlay]]
* [[How to create foliage height based on an Inference Overlay]]
* [[How to import trees based on an Inference Overlay]]
* [[How to import trees based on an Inference Overlay]]
* [[How to detect solar panels using an Inference Overlay]]
* [[How to detect solar panels using an Inference Overlay]]

Latest revision as of 11:19, 19 December 2024

Trees detected with Inference Overlay.

The AI Inference Overlay is a Grid Overlay which can spatially identify features using one or more Prequel Grids. Features are identified using a Convolution Neural Network that used a limited amount of proposal regions (RCNN). This Neural Network takes a subsection (window) of the input grid and either;

It is not possible to run the convolution network on the grid as a whole. Therefore, a marching window strategy is applied instead, where the window is moved over the input grid with a configurable stride. This window takes the input values of one or more grids and puts these into tensors representing either floating point values or color channels (red, green and blue). Depending on the dataset used to train the neural network, the tensor values are normalized based on a particular value range. For example, a relative height input tensor for a foliage neural network trained on height data can be normalized using a range of 0 to 40 meters, when 40 meters is considered the largest tree height in the Netherlands.

Foliage Example

Animation of inference with a moving window and Bounding Box detection and a stride fraction of 0.5.

Using a Satellite Overlay of 0.1m detail, foliage features can be identified using an Inference Overlay and enhanced with a Digital Terrain Model Overlay (DTM), a WCS Overlay representing the DSM, Combo Overlay to combine these and an optionally an iterative Max Overlay to enhance the foliage height. For more information, see this how-to.