AI Article Synopsis
- Forest damage has increased in Hungary over recent decades, and remote sensing techniques utilizing Sentinel-2 satellite imagery and Google Earth Engine have been employed to monitor these changes efficiently.
- The study analyzed vegetation indices to detect forest disturbances, such as drought and frost damage, specifically in the Nagyerdő forest from 2017 to 2020, revealing differences in tree species responses.
- The accuracy of the detection methods was validated with high precision, showcasing the potential of this approach for broader monitoring across Hungary using a combination of satellite data, field measurements, and machine learning.
Article Abstract
Forest damage has become more frequent in Hungary in the last decades, and remote sensing offers a powerful tool for monitoring them rapidly and cost-effectively. A combined approach was developed to utilise high-resolution ESA Sentinel-2 satellite imagery and Google Earth Engine cloud computing and field-based forest inventory data. Maps and charts were derived from vegetation indices (NDVI and Z∙NDVI) of satellite images to detect forest disturbances in the Hungarian study site for the period of 2017-2020. The NDVI maps were classified to reveal forest disturbances, and the cloud-based method successfully showed drought and frost damage in the oak-dominated Nagyerdő forest of Debrecen. Differences in the reactions to damage between tree species were visible on the index maps; therefore, a random forest machine learning classifier was applied to show the spatial distribution of dominant species. An accuracy assessment was accomplished with confusion matrices that compared classified index maps to field-surveyed data, demonstrating 99.1% producer, 71% user, and 71% total accuracies for forest damage and 81.9% for tree species. Based on the results of this study and the resilience of Google Earth Engine, the presented method has the potential to be extended to monitor all of Hungary in a faster, more accurate way using systematically collected field-data, the latest satellite imagery, and artificial intelligence.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC10817504 | PMC |
| http://dx.doi.org/10.3390/jimaging10010014 | DOI Listing |
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