Abstract
In the case of ongoing wildfire events, timely information on current fire parameters is crucial for informed decision making. Satellite imagery can provide valuable information in this regard, since thermal sensors can detect the exact location and intensity of an active fire at the moment the satellite passes over. This information can be derived and distributed in near-real time, allowing for a picture of current fire activity. However, the derivation of the size and shape of an already affected area is more complex and therefore most often not available within a short time frame. For urgent decision making though, it would be desirable to have this information available in near-real time, and on a large scale. The approach presented here works fully automatic and provides perimeters of burnt areas within two hours after the satellite scene acquisition. It uses the red and near-infrared bands of mid-resolution imagery to facilitate continental-scale monitoring of recently occurred burnt areas. To allow for a high detection capacity independent of the affected vegetation type, segmentation thresholds are derived dynamically from contextual information. This is done by using a Morphological Active Contour approach for perimeter determination. The results are validated against semi-automatically derived burnt areas for five wildfire incidents in Europe. Furthermore, these results are compared with three widely used burnt area datasets on a country-wide scale. It is shown that a high detection quality can be reached in near real-time. The large-scale inter-comparison shows that the results coincide with 63% to 76% of the burnt area in the reference datasets. While these established datasets are only available with a time lag of several months or are created by using manual interaction, the presented approach produces results in near-real time fully automatically. This work is therefore supposed to represent a valuable improvement in wildfire related rapid damage assessment.
Highlights
Forest fire is a natural phenomenon that has always played a significant role in the evolution of ecosystems, influencing ecological patterns and processes on a global scale
The analysis shows a percentage of 62.9% regarding overlapping area. 65.6% of Fire_cci 5.1 Burnt Area (BA) polygons are intersected by DLR NRT data
The goal of this study is to develop a fully automatic methodology for burnt area monitoring on a continental scale in near-real time
Summary
Forest fire is a natural phenomenon that has always played a significant role in the evolution of ecosystems, influencing ecological patterns and processes on a global scale. This includes vegetation distribution and structure, as well as the carbon cycle [1]. The vegetation communities adapt well to fire incidences This results in ecologically beneficial effects, such as increased species heterogeneity [5]. At the same time, wildfires are regarded to be one of the most devastating natural hazards globally They pose a threat to human lives and property, and can lead to the irreversible destruction of ecosystems. Developed fire regimes are expected to change in the future, which further increases the requirement for fire management worldwide [1]
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