Hyperspectral data simulation (Sentinel-2 to AVIRIS-NG) for improved wildfire fuel mapping, boreal Alaska
Document Type: Journal Article
Author(s): Anushree Badola; Santosh Panda; Dar A. Roberts; Christine F. Waigl; Uma S. Bhatt; Christopher William Smith; Randi R. Jandt
Publication Year: 2021

Cataloging Information

  • AVIRIS - Airborne Visible Infrared Imaging Spectrometer
  • boreal forest
  • hyperspectral
  • Sentinel 2
  • simulation
  • spectral reconstruction
  • UPDM - Uniform Pattern Decomposition Method
Record Maintained By:
Record Last Modified: June 6, 2021
FRAMES Record Number: 63769


Alaska has witnessed a significant increase in wildfire events in recent decades that have been linked to drier and warmer summers. Forest fuel maps play a vital role in wildfire management and risk assessment. Freely available multispectral datasets are widely used for land use and land cover mapping, but they have limited utility for fuel mapping due to their coarse spectral resolution. Hyperspectral datasets have a high spectral resolution, ideal for detailed fuel mapping, but they are limited and expensive to acquire. This study simulates hyperspectral data from Sentinel-2 multispectral data using the spectral response function of the Airborne Visible/Infrared Imaging Spectrometer-Next Generation (AVIRIS-NG) sensor, and normalized ground spectra of gravel, birch, and spruce. We used the Uniform Pattern Decomposition Method (UPDM) for spectral unmixing, which is a sensor-independent method, where each pixel is expressed as the linear sum of standard reference spectra. The simulated hyperspectral data have spectral characteristics of AVIRIS-NG and the reflectance properties of Sentinel-2 data. We validated the simulated spectra by visually and statistically comparing it with real AVIRIS-NG data. We observed a high correlation between the spectra of tree classes collected from AVIRIS-NG and simulated hyperspectral data. Upon performing species level classification, we achieved a classification accuracy of 89% for the simulated hyperspectral data, which is better than the accuracy of Sentinel-2 data (77.8%). We generated a fuel map from the simulated hyperspectral image using the Random Forest classifier. Our study demonstrated that low-cost and high-quality hyperspectral data can be generated from Sentinel-2 data using UPDM for improved land cover and vegetation mapping in the boreal forest.

Online Link(s):
Badola, Anushree; Panda, Santosh K.; Roberts, Dar A.; Waigl, Christine F.; Bhatt, Uma S.; Smith, Christopher W.; Jandt, Randi R. 2021. Hyperspectral data simulation (Sentinel-2 to AVIRIS-NG) for improved wildfire fuel mapping, boreal Alaska. Remote Sensing 13(9):1693.