A novel method to simulate AVIRIS-NG hyperspectral image from Sentinel-2 image for improved vegetation/wildfire fuel mapping, boreal Alaska

•- Vegetation mapped from simulated AVIRIS-NG image offers greater details and accuracy.•− 33% improvement in the new vegetation map accuracy.•- A novel approach to generate improved vegetation maps for Alaska’s boreal domain. Detailed vegetation maps are one of the primary inputs for forest and wil...

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Bibliographic Details
Published in:International journal of applied earth observation and geoinformation Vol. 112; p. 102891
Main Authors: Badola, Anushree, Panda, Santosh K., Roberts, Dar A., Waigl, Christine F., Jandt, Randi R., Bhatt, Uma S.
Format: Journal Article
Language:English
Published: Elsevier B.V 01.08.2022
Elsevier
Subjects:
Alaska
algorithms
Betula
Boreal forest
cost effectiveness
Endmembers
forests
fuels
gravel
Hyperspectral data
hyperspectral imagery
image analysis
Picea
Simulation
spatial data
Spectral library
spectrometers
spectroradiometers
UPDM
vegetation maps
wildfires
wildland fire management
Alaska
Boreal forest
Endmembers
Spectral library
UPDM
Hyperspectral data
Simulation
ISSN:1569-8432, 1872-826X
Online Access:Get full text
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Summary:•- Vegetation mapped from simulated AVIRIS-NG image offers greater details and accuracy.•− 33% improvement in the new vegetation map accuracy.•- A novel approach to generate improved vegetation maps for Alaska’s boreal domain. Detailed vegetation maps are one of the primary inputs for forest and wildfire management. Hyperspectral remote sensing is a proven technique for detailed and accurate vegetation mapping. However, the availability of recent hyperspectral imagery in Alaska is limited because of the logistics and high cost involved in its acquisition. In this study, we simulated AVIRIS-NG (Airborne Visible InfraRed Imaging Spectrometer - Next Generation) hyperspectral data from widely available Sentinel-2 multispectral data using the Universal Pattern Decomposition Method (UPDM). The UPDM is a spectral unmixing technique that uses detailed ground spectra of vegetation classes and the Spectral Response Functions of AVIRIS-NG and Sentinel-2 sensors to simulate imagery with the same number of bands and spectral resolution as an AVIRIS-NG image. We simulated three images (each covering an area of 100 km × 100 km) from two ecoregions to test portability of the approach. We collected ground spectra of vegetation and bare ground during summers (2019–2021) using a PSR+ 3500 hand-held spectroradiometer and created a spectral library for this study. The Iterative Endmember Selection (IES) algorithm was used to optimize the spectral library and to select the most representative endmembers for simulation: birch, spruce, and gravel. We validated the simulated hyperspectral imagery by comparing it with available AVIRIS-NG images. The simulated image was visually and spectrally similar to the AVIRIS-NG image (RMSE of 0.03 and 0.02 for birch and spruce spectra, respectively). We applied the Random Forest image classification model to derive detailed vegetation maps from the simulated images. Our vegetation map showed an improvement of 33% in the map accuracy compared to the LANDFIRE EVT map. This study demonstrated an efficient and cost-effective approach to derive detailed vegetation maps at the Sentinel scene scale by simulating hyperspectral images in Google’s cloud environment. It offers a novel pathway to generate detailed vegetation and fuel maps for the whole boreal region of Alaska to aid effective forest and fire management.
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ISSN:1569-8432
1872-826X
DOI:10.1016/j.jag.2022.102891