A disturbance weighting analysis model (DWAM) for mapping wildfire burn severity in the presence of forest disease

Forest ecosystems are subject to recurring fires as one of their most significant disturbances. Accurate mapping of burn severity is crucial for post-fire land management and vegetation regeneration monitoring. Remote-sensing-based monitoring of burn severity faces new challenges when forests experi...

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Bibliographic Details
Published in:Remote sensing of environment 2019-02, Vol.221, p.108-121
Main Authors: He, Yinan, Chen, Gang, De Santis, Angela, Roberts, Dar A., Zhou, Yuyu, Meentemeyer, Ross K.
Format: Article
Language:English
Subjects:
Airborne sensing
AVIRIS
Burn severity
Disturbance
Disturbance Weighting Analysis Model (DWAM)
Disturbances
Environmental changes
Fires
Forest ecosystems
Forestry
Forests
Infectious diseases
Infrared imaging
Infrared spectrometers
Land management
Landsat
Landsat satellites
Landscape
Landscape epidemiology
Lookup tables
Mapping
MESMA
Plant diseases
Radiative transfer
Radiative transfer models
Regeneration
Remote monitoring
Remote sensing
Satellite imagery
Sudden oak death
Terrestrial ecosystems
Trees
Weighting
Wildfires
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Summary:Forest ecosystems are subject to recurring fires as one of their most significant disturbances. Accurate mapping of burn severity is crucial for post-fire land management and vegetation regeneration monitoring. Remote-sensing-based monitoring of burn severity faces new challenges when forests experience both fire and non-fire disturbances, which may change the biophysical and biochemical properties of trees in similar ways. In this study, we develop a Disturbance Weighting Analysis Model (DWAM) for accurately mapping burn severity in a forest landscape that is jointly affected by wildfire and an emerging infectious disease – sudden oak death. Our approach treats burn severity in each basic mapping unit (e.g., 30 m grid from a post-fire Landsat image) as a linear combination of burn severity of trees affected (diseased) and not affected by the disease (healthy), weighted by their areal fractions in the unit. DWAM is calibrated using two types of inputs: i) look-up tables (LUTs) linking burn severity and post-fire spectra for diseased and healthy trees, derived from field observations, hyperspectral sensors [e.g., Airborne Visible InfraRed Imaging Spectrometer (AVIRIS)], and radiative transfer models; and ii) pre-fire fractional maps of diseased and healthy trees, derived by decomposing a pre-fire Landsat image using Multiple Endmember Spectral Mixture Analysis (MESMA). Considering the presence of tree disease in DWAM improved the overall map accuracy by 42%. The superior performance is consistent across all three stages of disease progression. Our approach demonstrates the potential for improved mapping of forest burn severity by reducing the confounding effects of other biotic disturbances. •We propose a new model DWAM for mapping burn severity in a disease-impacted forest.•Considering the presence of tree disease improves the overall map accuracy by 42%.•The superior performance is consistent across all stages of disease progression.•DWAM can be straightforwardly calibrated for mapping burn severity in other regions.
ISSN:0034-4257
1879-0704
DOI:10.1016/j.rse.2018.11.015