Difference between revisions of "Supervised Classifications using Google Earth Engine"
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=Getting Started= |
=Getting Started= |
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We will now begin preparing the image(s) that we will be classifying. |
We will now begin preparing the image(s) that we will be classifying. |
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+ | Displaying images in Google Earth can take some getting used to. I am aware that I have not shown you how to create an image yet, bear with me. This step is important and will be repeated throughout the tutorial which is why I want to show you now. The application in itself is fairly simple, it takes one line: |
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+ | <syntaxhighlight lang="javascript">Map.addLayer(image)</syntaxhighlight> |
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+ | It is as simple as that; however, there are likely two issues that you will immediately notice: |
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+ | #You will notice that the image is dark. This is because it will automatically set the range of pixel values from 0-1. This is typically not enough to represent an image. |
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+ | #Once this issue is fixed, the colours will look off. This is due to it automatically setting bands 1, 2, and 3 as R, G, and B. These are not the proper bands for the colours. |
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+ | Remedying these issues is fairly simple, just follow these steps: |
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+ | #Navigate to the band settings: |
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+ | #:[[File:BandSettings.png|500|center|thumb|Note the darkness of my image.]] |
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==Getting Images== |
==Getting Images== |
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Now that we have a variable named L8 that is linked to the Landsat 8 collection that we want, we can begin to filter images and choose what we want. For this example, I will create a cloud-free mosaic of Fort McMurray in the month after the major fire that swept through in May of 2016. I have created two functions for this, one that creates a cloud mask and the other that creates a simple composite from a collection of images. |
Now that we have a variable named L8 that is linked to the Landsat 8 collection that we want, we can begin to filter images and choose what we want. For this example, I will create a cloud-free mosaic of Fort McMurray in the month after the major fire that swept through in May of 2016. I have created two functions for this, one that creates a cloud mask and the other that creates a simple composite from a collection of images. |
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− | + | *By utilizing the 'BQA' band present in Landsat 8 imagery, we can create a cloud mask to remove any cloud pixels that may alter the result. I created a function that will select any pixel that has cloud cover with even moderate confidence. The function will return a mask that removes all of these pixels from an image. Note that I have commented on this one fairly heavily due to it be slightly confusing at first. |
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− | + | **I should add again, if you haven't already explored all the bands of your chosen imagery, do. There are plenty of interesting things that can be used. |
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<syntaxhighlight lang="javascript"> |
<syntaxhighlight lang="javascript"> |
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// Cloud mask for L8 imagery |
// Cloud mask for L8 imagery |
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− | + | *Now onto the composite. This is a much simpler function, it simply intakes a collection of images and uses the built in 'simpleComposite' function to combine them into the best possible image. |
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<syntaxhighlight lang="javascript"> |
<syntaxhighlight lang="javascript"> |
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// Function to create composite |
// Function to create composite |
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};</syntaxhighlight> |
};</syntaxhighlight> |
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− | + | *With the two main functions created, we can now use a few lines to create our final image. |
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<syntaxhighlight lang="javascript"> |
<syntaxhighlight lang="javascript"> |
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// Select all images within June 2016 that touch the extent and have the least removed from the cloud mask |
// Select all images within June 2016 that touch the extent and have the least removed from the cloud mask |
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==Preparing Images== |
==Preparing Images== |
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===Adding Bands=== |
===Adding Bands=== |
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=Getting Training Data= |
=Getting Training Data= |
Revision as of 10:40, 16 November 2020
Introduction
Getting Started
We will now begin preparing the image(s) that we will be classifying.
Displaying Images
Displaying images in Google Earth can take some getting used to. I am aware that I have not shown you how to create an image yet, bear with me. This step is important and will be repeated throughout the tutorial which is why I want to show you now. The application in itself is fairly simple, it takes one line:
Map.addLayer(image)
It is as simple as that; however, there are likely two issues that you will immediately notice:
- You will notice that the image is dark. This is because it will automatically set the range of pixel values from 0-1. This is typically not enough to represent an image.
- Once this issue is fixed, the colours will look off. This is due to it automatically setting bands 1, 2, and 3 as R, G, and B. These are not the proper bands for the colours.
Remedying these issues is fairly simple, just follow these steps:
- Navigate to the band settings:
Getting Images
Google Earth Engine has a large selection of remote sensing data to choose from. In this example, I will be using the ' USGS Landsat 8 Collection 1 Tier 1 Raw Scenes' collection. This is a collection of the highest quality images available through Landsat 8.
Define a variable 'L8' so that you can easily reference this entire collection:
var L8 = ee.ImageCollection('LANDSAT/LC08/C01/T1');
Creating a Cloud-Free Mosaic
Now that we have a variable named L8 that is linked to the Landsat 8 collection that we want, we can begin to filter images and choose what we want. For this example, I will create a cloud-free mosaic of Fort McMurray in the month after the major fire that swept through in May of 2016. I have created two functions for this, one that creates a cloud mask and the other that creates a simple composite from a collection of images.
- By utilizing the 'BQA' band present in Landsat 8 imagery, we can create a cloud mask to remove any cloud pixels that may alter the result. I created a function that will select any pixel that has cloud cover with even moderate confidence. The function will return a mask that removes all of these pixels from an image. Note that I have commented on this one fairly heavily due to it be slightly confusing at first.
- I should add again, if you haven't already explored all the bands of your chosen imagery, do. There are plenty of interesting things that can be used.
// Cloud mask for L8 imagery
var L8CloudMask = function(L8) {
var qa = L8.select('BQA'); //selects the BQA (quality) band
var CloudOrShadow = qa.bitwiseAnd(1<<4) //chooses pixels where cloud is present
.and(qa.bitwiseAnd(1<<6)) //and pixels where cloud confidence ic greater than 34%
.or(qa.bitwiseAnd(1<<8)) //or pixels where cloud shadow confidence is greater than 34%
.or(qa.bitwiseAnd(1<<12)); //or pixels where cirrus confidence is greater than 34%
var masked = L8.mask(); //creates a mask
return L8.updateMask(CloudOrShadow.not()).updateMask(masked); //updates mask to remove any pixels as described above in 'CloudOrShadow'
};
- Now onto the composite. This is a much simpler function, it simply intakes a collection of images and uses the built in 'simpleComposite' function to combine them into the best possible image.
// Function to create composite
var createComp = function(collection) {
var comp = ee.Algorithms.Landsat.simpleComposite({
collection: collection,
asFloat: true
});
return comp;
};
- With the two main functions created, we can now use a few lines to create our final image.
// Select all images within June 2016 that touch the extent and have the least removed from the cloud mask
var after = ee.ImageCollection('LANDSAT/LC08/C01/T1')
.filterDate('2016-06-01', '2016-06-30')
.filterBounds(extent)
.map(L8CloudMask);
// Create composite of images chosen above
var compAfter = createComp(after);
// Clip to extent
var clipAfter = compAfter.clip(extent);
Preparing Images
Adding Bands
Getting Training Data
Create Landcover Polygons
Gather Data from Polygons
Create Training and Validation Sets
Assess Useability of Data
histograms etc
Classification
Test on Validation Data Set
error matrix
Run on Chosen Image
===Calculating Area of Each Class