Leveraging High-Resolution Satellite Imagery and Gradient Boosting for Invasive Weed Mapping

An introduced pasture grass (Andropogon gayanus - gamba grass) is spreading through the tropical savannas of northern Australia, with detrimental ecosystem consequences including increased fire intensity. In order to monitor and manage the spread of gamba grass, a scalable solution for mapping its d...

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Bibliographic Details
Published inIEEE journal of selected topics in applied earth observations and remote sensing Vol. 13; pp. 4443 - 4450
Main Authors Shendryk, Yuri, Rossiter-Rachor, Natalie A., Setterfield, Samantha A., Levick, Shaun R.
Format Journal Article
LanguageEnglish
Published Piscataway IEEE 2020
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Environmental conditions
Extreme gradient boosting (XGBoost)
Feature extraction
Fires
gamba grass
Grasses
Haliporoides diomedeae
High resolution
Hyperspectral sensors
Image resolution
Imagery
Invasive plants
Learning algorithms
Machine learning
Mapping
Pasture
Probability theory
remote sensing
Resolution
Satellite imagery
Satellites
Savannahs
Sensors
Spaceborne remote sensing
Spatial resolution
Spectral bands
Tropical climate
weed
WorldView-3
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Summary:An introduced pasture grass (Andropogon gayanus - gamba grass) is spreading through the tropical savannas of northern Australia, with detrimental ecosystem consequences including increased fire intensity. In order to monitor and manage the spread of gamba grass, a scalable solution for mapping its distribution over large areas is required. Recent developments in machine learning have proven useful for distinguishing vegetation types in satellite imagery in an automated manner. In this study, we collected field data for supervised learning of very high-resolution (0.3 m) WorldView-3 satellite imagery and tuned the hyperparameters of an extreme gradient boosting classifier to produce a viable solution for detecting the probability of gamba grass presence. To evaluate the performance of WorldView-3 imagery in discriminating gamba grass, we tested the utility of predictors derived from: 1) spectral bands; 2) textural features; 3) spectral indices; and 4) all predictors combined. Our results suggest that gamba grass presence can be mapped from space with an accuracy of up to 91% under optimal environmental conditions.
ISSN:1939-1404
2151-1535
DOI:10.1109/JSTARS.2020.3013663