Landviewer Now Features Change Detection That Runs In Browser

The major utilization of remote sensing data has been to compare images of an area taken at different times and identify the changes it underwent. With a wealth of long-term satellite imagery currently in open use, detecting such changes manually would be time-consuming and most likely inaccurate. EOS Data Analytics stepped in by introducing the automated Change Detection tool to its flagship product LandViewer, which ranks among the most capable cloud tools for satellite imagery search and analysis in today’s market.

Unlike the methods involving neural networks that identify changes in the previously extracted features, the change detection algorithm implemented by EOS is using a pixel-based strategy, meaning that changes between two raster multi-band images are mathematically calculated by subtracting the pixel values for one date from the pixel values of the same coordinates for another date. This new signature feature is designed to automate your change detection task and deliver accurate results in fewer steps and in a fraction of the time needed for change detection with ArcGIS, QGIS or another image-processing GIS software.

Change detection interface. Images of Beirut city coastline selected for tracing the developments of the past years.

Unlimited scope of applications ‒ from farming to environmental monitoring

One of the main goals set by EOS team was to make the complex process of change detection in remote sensing data equally accessible and easy for non-expert users coming from non-GIS industries.

With LandViewer’s change detection tool, farmers can quickly identify the areas on their fields that were damaged by hail, storm or flooding. In forest management, satellite image detection of changes will come in handy for estimation of the burned areas following the wildfire and spotting the illegal logging or encroachment on forest lands. Observing the rate and extent of climate changes occurring to the planet (such as polar ice melt, air and water pollution, natural habitat loss due to urban expansion) is an ongoing task of environmental scientists, who may now have it done online in a matter of minutes. By studying the differences between the past and present using the change detection tool and years of satellite data in LandViewer, all these industries can also forecast future changes.

Top change detection use cases: flood damage and deforestation

A picture is worth a thousand words, and the capabilities of satellite image change detection in LandViewer can be best demonstrated on real-life examples.

Forests that still cover around a third of the world’s area are disappearing at an alarming rate, mostly due to human activities such as farming, mining, grazing of livestock, logging, and also the natural factors like wildfires. Instead of massive ground surveying of thousands of forest acres, a forestry technician can regularly monitor the forest safety with a pair of satellite images and the automated change detection based on NDVI (Normalized Difference Vegetation Index).

How does it work? NDVI is a known means of determining vegetation health. By comparing the satellite image of the intact forest with the recent one acquired after the trees were cut down, LandViewer will detect the changes and generate a difference image highlighting the deforestation spots, which can further be downloaded by users in .jpg, .png or .tiff format. The surviving forest cover will have positive values, while the cleared areas will have negative ones and be shown in red hues indicating there’s no vegetation present.

A difference image showing the extent of deforestation in Madagascar between 2016 and 2018; generated from two Sentinel-2 satellite images.

Another widespread use case for change detection would be agricultural flood damage assessment, which is of most interest to crop growers and insurance companies. Whenever flooding has taken a heavy toll on your harvest, the damage can be quickly mapped and measured with the help of NDWI-based change detection algorithms.

Results of Sentinel-2 scene change detection: the red and orange areas represent the flooded part of the field; the surrounding fields are green, meaning they avoided the damage. California flooding, February 2017.

How to run change detection in LandViewer

There are two ways you can launch the tool and start finding differences on multi-temporal satellite images: by clicking the right menu icon “Analysis tools” or from the Comparison slider ‒ whichever is more convenient. Currently, change detection is performed on optical (passive) satellite data only; addition of the algorithms for active remote sensing data is scheduled for future updates.

For more details, please read this guide to LandViewer’s change detection tool.

Or start exploring the latest capabilities of LandViewer on your own.

Say thanks for this article (0)
The community is supported by:
Become a sponsor
#
#0.30m #0.5m #Airbus #Deep Learning #Financial Services #Geospatial analytics #Maxar #Multispectral #Optical #Planet #Vegetation Indexes
How Satellite Data is Bringing Value to Commodity Trading
Aleks Buczkowski 07.15.2022
AWESOME 6
#SAR
EnMAP launch on 1st April 2022 in LIVE-Stream
Stefan Mühlbauer 03.31.2022
AWESOME 0
#0.30m #0.5m #10m #1m #30m #Agriculture #Airbus #Copernicus #Landsat #Multispectral #Optical #Vegetation Indexes
Beyond NDVI: What are vegetation indices, and how are they used in precision farming?
Aleks Buczkowski 10.15.2022
AWESOME 2
Next article

Lockheed Martin develops AI model for satellite imagery analysis

Satellite imagery analysis is fast becoming a highly lucrative business model for both commercial players and defense contractors. Just last month, Airbus launched a new geospatial tool which would make planet-wide change detection possible in near-real-time. And now, Lockheed Martin has announced a satellite imagery recognition system which uses open-source deep learning libraries to identify and classify large datasets quickly.

Called Global Automated Target Recognition (GATR), the artificial intelligence model uses Maxar’s Geospatial Big Data platform to access the latter’s 100 petabyte treasure trove of satellite imagery library and millions of curated data labels. The Cloud-based system promises to save image analysts the trouble of spending countless hours manually categorizing and labeling items within an image.

During a public demo at GEOINT 2019 conference, GATR was able to search the entire state of Pennsylvania – 120,000 square kilometers – for fracking sites in only 2 hours. So, even if someone who is not an expert on oil production sites is looking for information on the same, they can leave the traditionally-manual process to GATR.

Lockheed Martin says the system can identify characteristics of an object area or target with an accuracy of over 90%. The self-learning model can recognize ships, airplanes, buildings, seaports, and many other commercial categories, freeing up analysts for higher-level tasks.

Mark Pritt, a senior fellow at Lockheed Martin and principal investigator for GATR, adds, “This system teaches itself the defining characteristics of an object, saving valuable time training an algorithm and ultimately letting an image analyst focus more on their mission.”

Lockheed Martin insists that it has an advantage over other players offering imagery analysis because its system uses commercial imagery from vendors like Maxar and Planet to ensure global coverage. “With our tool, the user can draw a box anywhere in the world and hit the button,” Pritt tells SpaceNews in an interview. “The system will go search for objects of interest such as fracking wells, airplanes or refugee camps.”

Read on
Search