https://github.com/mortcanty/earthengine

Change Detection with Google Earth Engine Imagery
https://github.com/mortcanty/earthengine

Last synced: 8 days ago
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Change Detection with Google Earth Engine Imagery

• Host: GitHub
• URL: https://github.com/mortcanty/earthengine
• Owner: mortcanty
• License: mit
• Created: 2017-02-23T15:35:53.000Z (over 7 years ago)
• Default Branch: master
• Last Pushed: 2019-03-23T11:59:26.000Z (over 5 years ago)
• Last Synced: 2024-07-23T02:39:54.072Z (4 months ago)
• Language: Python
• Size: 6.83 MB
• Stars: 139
• Watchers: 15
• Forks: 52
• Open Issues: 5
• Metadata Files:
  • Readme: README.md
  • Contributing: CONTRIBUTING.md
  • License: LICENSE.txt

Awesome Lists containing this project

• awesome-remote-sensing-change-detection - Canty M J. Change Detection with Google Earth Engine Imagery

README

        
# Change Detection with Google Earth Engine Imagery

A simple Flask web application for performing change detection tasks with 

Google Earth Engine imagery.    

The AppEngine version (web version) is for demonstration only and has very limited functionality.

Exporting results to Google Drive or to Earth Engine assets is in particular not possible. 

The local version runs in a Docker container serving the Flask web application on __localhost:5000__.

Assuming you have been authenticated (see below) to the Earth Engine, you can carry out the following tasks:

 1. Run the iMAD (iteratively re-weighted MAD) algorithm on Landsat 5, 7, 8 and Sentinel-2 optical/infrared bitemporal imagery. 

 

     

	A. A. Nielsen (2007). The Regularized Iteratively Reweighted MAD Method for Change Detection in Multi- and Hyperspectral Data.

	 M. J.Canty (2014). 

	Image Analysis, Classification and Change Detection in Remote Sensing, 3rd Ed., CRC Press 2014; 

	

 2. Perform automatic radiometric normalization of a sequence full optical/infrared scenes.

    

       M. J. Canty and A. A. Nielsen (2008). Automatic Radiometric Normalization of Multitemporal Satellite Imagery with the Iteratively Re-weighted MAD Transformation.

 

	

	

 3. Run the (sequential) omnibus algorithm on polarimetric SAR multitemporal data on Sentinel-1 dual pol, diagonal only, or single pol images.

 

	  

	K. Conradsen et al. (2016). Determining the points of

	change in time series of polarimetric SAR data. IEEE TGRS 54 (5) 3007-3024.

	

 4. Perform principal components analysis in visual/infrared full scenes.	

 5. Export imagery to your Earth Engine assets folder or to Google Drive for off-line local processing, 

 for example with  SARDocker.

 

### Installation and execution

 1. Install Docker

 

 2. In a command window execute the command

 

 		docker run -it -p 5000:5000 --name=ee mort/eedocker 

 		

 	or, if you are on a Raspberry Pi

 	

 		docker run -it -p 5000:5000 --name=ee mort/rpi-eedocker		

 		

 3. If the container is not found it will be automatically downloaded from Dockerhub and

 started. At the container prompt execute the command

 

 		earthengine authenticate

 	

 	and follow the instructions. You will have to copy the given URL and paste it into your local browser.

 	

 4. After successful authentication the credentials are saved to the container. Now run the command

 

 		./app.py

 	

 	and point your browser to 

 	

 		localhost:5000

 		

 	to start work.

 		

 5. When finished, hit 

 

 		Ctrl C 

 		

 	in the command window to stop the Flask application server and 

 

 		exit 

 		

 	to leave the container. The container will then stop.

 		

 6. Re-start and enter the container with

 

 		docker start -ai ee

 		

 7. Run the command

 

	    ./app.py

		

	to re-start the server.