Code Editor (JavaScript)
// First gather the training data for a random forest classifier.
// Let's use MCD12Q1 yearly landcover for the labels.
var landcover = ee.ImageCollection('MODIS/061/MCD12Q1')
.filterDate('2022-01-01', '2022-12-31')
.first()
.select('LC_Type1');
// A region of interest for training our classifier.
var region = ee.Geometry.BBox(17.33, 36.07, 26.13, 43.28);
// Training features will be based on a Landsat 8 composite.
var l8 = ee.ImageCollection('LANDSAT/LC08/C02/T1')
.filterBounds(region)
.filterDate('2022-01-01', '2023-01-01');
// Draw the Landsat composite, visualizing true color bands.
var landsatComposite = ee.Algorithms.Landsat.simpleComposite({
collection: l8,
asFloat: true
});
Map.addLayer(landsatComposite, {
min: 0,
max: 0.3,
bands: ['B3', 'B2', 'B1']
}, 'Landsat composite');
// Make a training dataset by sampling the stacked images.
var training = landcover.addBands(landsatComposite).sample({
region: region,
scale: 30,
// With export to Classifier we can bump this higher to say 10,000.
numPixels: 1000
});
var classifier = ee.Classifier.smileRandomForest({
// We can also increase the number of trees higher to ~100 if needed.
numberOfTrees: 3
}).train({features: training, classProperty: 'LC_Type1'});
// Create an export classifier task to run.
var assetId = 'projects/<project-name>/assets/<asset-name>'; // <> modify these
Export.classifier.toAsset({
classifier: classifier,
description: 'classifier_export',
assetId: assetId
});
// Load the classifier after the export finishes and visualize.
var savedClassifier = ee.Classifier.load(assetId)
var landcoverPalette = '05450a,086a10,54a708,78d203,009900,c6b044,dcd159,' +
'dade48,fbff13,b6ff05,27ff87,c24f44,a5a5a5,ff6d4c,69fff8,f9ffa4,1c0dff';
var landcoverVisualization = {
palette: landcoverPalette,
min: 0,
max: 16,
format: 'png'
};
Map.addLayer(
landsatComposite.classify(savedClassifier),
landcoverVisualization,
'Upsampled landcover, saved');
Python setup
See the
Python Environment page for information on the Python API and using
geemap for interactive development.
import ee
import geemap.core as geemap
Colab (Python)
# First gather the training data for a random forest classifier.
# Let's use MCD12Q1 yearly landcover for the labels.
landcover = (ee.ImageCollection('MODIS/061/MCD12Q1')
.filterDate('2022-01-01', '2022-12-31')
.first()
.select('LC_Type1'))
# A region of interest for training our classifier.
region = ee.Geometry.BBox(17.33, 36.07, 26.13, 43.28)
# Training features will be based on a Landsat 8 composite.
l8 = (ee.ImageCollection('LANDSAT/LC08/C02/T1')
.filterBounds(region)
.filterDate('2022-01-01', '2023-01-01'))
# Draw the Landsat composite, visualizing true color bands.
landsatComposite = ee.Algorithms.Landsat.simpleComposite(
collection=l8, asFloat=True)
Map = geemap.Map()
Map # Render the map in the notebook.
Map.addLayer(landsatComposite, {
'min': 0,
'max': 0.3,
'bands': ['B3', 'B2', 'B1']
}, 'Landsat composite')
# Make a training dataset by sampling the stacked images.
training = landcover.addBands(landsatComposite).sample(
region=region,
scale=30,
# With export to Classifier we can bump this higher to say 10,000.
numPixels=1000
)
# We can also increase the number of trees higher to ~100 if needed.
classifier = ee.Classifier.smileRandomForest(
numberOfTrees=3).train(features=training, classProperty='LC_Type1')
# Create an export classifier task to run.
asset_id = 'projects/<project-name>/assets/<asset-name>' # <> modify these
ee.batch.Export.classifier.toAsset(
classifier=classifier,
description='classifier_export',
assetId=asset_id
)
# Load the classifier after the export finishes and visualize.
savedClassifier = ee.Classifier.load(asset_id)
landcover_palette = [
'05450a', '086a10', '54a708', '78d203', '009900',
'c6b044', 'dcd159', 'dade48', 'fbff13', 'b6ff05',
'27ff87', 'c24f44', 'a5a5a5', 'ff6d4c', '69fff8',
'f9ffa4', '1c0dff']
landcoverVisualization = {
'palette': landcover_palette,
'min': 0,
'max': 16,
'format': 'png'
}
Map.addLayer(
landsatComposite.classify(savedClassifier),
landcoverVisualization,
'Upsampled landcover, saved')