Self-Adjusting Thresholding for Burnt Area Detection Based on Optical Images

Self-Adjusting Thresholding for Burnt Area Detection Based on Optical Images

Mapping of regional fires would make it possible to analyse their environmental, social and economic impact, as well as to develop better fire management systems. However, automatic mapping of burnt areas has proved to be a challenging task, due to the wide diversity of vegetation cover worldwide an...

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Bibliographic Details
Main Authors: Edyta Woźniak, Sebastian Aleksansdrowicz
Format: Article
Language:English
Published: MDPI AG 2019-11-01
Series:Remote Sensing
Subjects:
forest fires
automatic classification
regional mapping
Online Access:https://www.mdpi.com/2072-4292/11/22/2669
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spelling doaj-06575b53c63c4c9b9a90333fee201a392020-11-25T00:39:17ZengMDPI AGRemote Sensing2072-42922019-11-011122266910.3390/rs11222669rs11222669Self-Adjusting Thresholding for Burnt Area Detection Based on Optical ImagesEdyta Woźniak0Sebastian Aleksansdrowicz1Space Research Centre, Polish Academy of Sciences, Bartycka 18A, 00-716 Warsaw, PolandSpace Research Centre, Polish Academy of Sciences, Bartycka 18A, 00-716 Warsaw, PolandMapping of regional fires would make it possible to analyse their environmental, social and economic impact, as well as to develop better fire management systems. However, automatic mapping of burnt areas has proved to be a challenging task, due to the wide diversity of vegetation cover worldwide and the heterogeneous nature of fires themselves. Here, we present an algorithm for the automatic mapping of burnt areas using medium-resolution optical images. Although developed for Landsat images, it can be also applied to Sentinel-2 images without modification. The algorithm draws upon the classical concept of differences in pre- and post-fire reflectance, but also takes advantage of the object-oriented approach and a new threshold calculation method. It consists of four steps. The first concerns the calculation of spectral indices and their differences, together with differences in spectral layers based on pre- and post-fire images. In the second step, multiresolution segmentation and masking are performed (clouds, water bodies and non-vegetated areas are removed from further analysis). Thirdly, ‘core’ burnt areas are detected using automatically-adjusted thresholds. Thresholds are calculated on the basis of specific functions established for difference layers. The last step combines neighbourhood analysis and patch growing to define the final shape of burnt areas. The algorithm was tested in 27 areas located worldwide, and covered by various types of vegetation. Comparisons with manual interpretation show that the fully-automated classification is accurate. Over 82% of classifications were considered satisfactory (overall accuracy > 90%; user and producer accuracy > 70%).https://www.mdpi.com/2072-4292/11/22/2669forest firesautomatic classificationregional mapping
collection DOAJ
language English
format Article
sources DOAJ
author Edyta Woźniak
Sebastian Aleksansdrowicz
spellingShingle Edyta Woźniak
Sebastian Aleksansdrowicz
Self-Adjusting Thresholding for Burnt Area Detection Based on Optical Images
Remote Sensing
forest fires
automatic classification
regional mapping
author_facet Edyta Woźniak
Sebastian Aleksansdrowicz
author_sort Edyta Woźniak
title Self-Adjusting Thresholding for Burnt Area Detection Based on Optical Images
title_short Self-Adjusting Thresholding for Burnt Area Detection Based on Optical Images
title_full Self-Adjusting Thresholding for Burnt Area Detection Based on Optical Images
title_fullStr Self-Adjusting Thresholding for Burnt Area Detection Based on Optical Images
title_full_unstemmed Self-Adjusting Thresholding for Burnt Area Detection Based on Optical Images
title_sort self-adjusting thresholding for burnt area detection based on optical images
publisher MDPI AG
series Remote Sensing
issn 2072-4292
publishDate 2019-11-01
description Mapping of regional fires would make it possible to analyse their environmental, social and economic impact, as well as to develop better fire management systems. However, automatic mapping of burnt areas has proved to be a challenging task, due to the wide diversity of vegetation cover worldwide and the heterogeneous nature of fires themselves. Here, we present an algorithm for the automatic mapping of burnt areas using medium-resolution optical images. Although developed for Landsat images, it can be also applied to Sentinel-2 images without modification. The algorithm draws upon the classical concept of differences in pre- and post-fire reflectance, but also takes advantage of the object-oriented approach and a new threshold calculation method. It consists of four steps. The first concerns the calculation of spectral indices and their differences, together with differences in spectral layers based on pre- and post-fire images. In the second step, multiresolution segmentation and masking are performed (clouds, water bodies and non-vegetated areas are removed from further analysis). Thirdly, ‘core’ burnt areas are detected using automatically-adjusted thresholds. Thresholds are calculated on the basis of specific functions established for difference layers. The last step combines neighbourhood analysis and patch growing to define the final shape of burnt areas. The algorithm was tested in 27 areas located worldwide, and covered by various types of vegetation. Comparisons with manual interpretation show that the fully-automated classification is accurate. Over 82% of classifications were considered satisfactory (overall accuracy > 90%; user and producer accuracy > 70%).
topic forest fires
automatic classification
regional mapping
url https://www.mdpi.com/2072-4292/11/22/2669
work_keys_str_mv AT edytawozniak selfadjustingthresholdingforburntareadetectionbasedonopticalimages
AT sebastianaleksansdrowicz selfadjustingthresholdingforburntareadetectionbasedonopticalimages
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