Burned area estimations derived from Landsat ETM+ and OLI data: Comparing Genetic Programming with Maximum Likelihood and Classification and Regression Trees
Created by W.Langdon from
gp-bibliography.bib Revision:1.8129
- @Article{CABRAL:2018:IJPRS,
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author = "Ana I. R. Cabral and Sara Silva and Pedro C. Silva and
Leonardo Vanneschi and Maria J. Vasconcelos",
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title = "Burned area estimations derived from {Landsat ETM+ and
OLI} data: Comparing Genetic Programming with Maximum
Likelihood and Classification and Regression Trees",
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journal = "ISPRS Journal of Photogrammetry and Remote Sensing",
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volume = "142",
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pages = "94--105",
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year = "2018",
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keywords = "genetic algorithms, genetic programming, Burned area
mapping, Savana woodlands, Classification and
Regression Trees, Maximum Likelihood, Landsat
ETM+/OLI",
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ISSN = "0924-2716",
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DOI = "doi:10.1016/j.isprsjprs.2018.05.007",
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URL = "http://www.sciencedirect.com/science/article/pii/S0924271618301400",
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abstract = "Every year, large areas of savannas and woodlands burn
due to natural conditions and land management
practices. Given the relevant level of greenhouse gas
emissions produced by biomass burning in tropical
regions, it is becoming even more important to clearly
define historic fire regimes so that prospective
emission reduction management strategies can be well
informed, and their results Measured, Reported, and
Verified (MRV). Thus, developing tools for accurately,
and periodically mapping burned areas, based on cost
advantageous, expedite, and repeatable rigorous
approaches, is important. The main objective of this
study is to investigate the potential of novel Genetic
Programming (GP) methodologies for classifying burned
areas in satellite imagery over savannas and tropical
woodlands and to assess if they can improve over the
popular and currently applied methods of Maximum
Likelihood classification and Classification and
Regression Tree analysis. The tests are performed using
three Landsat images from Brazil (South America),
Guinea-Bissau (West Africa) and the Democratic Republic
of Congo (Central Africa). Burned areas were digitized
on-screen to produce mapped information serving as
surrogate ground-truth. Validation results show that
all methods provide an overestimation of burned area,
but GP achieves higher accuracy values in two of the
three cases. GP is the most versatile machine learning
method available today, but still largely underused in
remote sensing. This study shows that standard GP can
produce better results than two classical methods, and
illustrates its versatility and potential in becoming a
mainstream method for more difficult tasks involving
the large amounts of newly available data",
- }
Genetic Programming entries for
Ana Isabel Rosa Cabral
Sara Silva
Pedro C Silva
Leonardo Vanneschi
Maria Jose Vasconcelos
Citations