Applying Probability Theory for the Quality Assessment of a Wildfire Spread Prediction Framework Based on Genetic Algorithms

Applying Probability Theory for the Quality Assessment of a Wildfire Spread Prediction Framework Based on Genetic Algorithms

This work presents a framework for assessing how the existing constraints at the time of attending an ongoing forest fire affect simulation results, both in terms of quality (accuracy) obtained and the time needed to make a decision. In the wildfire spread simulation and prediction area, it is essen...

Full description

Bibliographic Details
Main Authors: Andrés Cencerrado, Ana Cortés, Tomàs Margalef
Format: Article
Language:English
Published: Hindawi Limited 2013-01-01
Series:The Scientific World Journal
Online Access:http://dx.doi.org/10.1155/2013/728414
id doaj-0ab525fa46f14fe3bf3f38b7b950144c
record_format Article
spelling doaj-0ab525fa46f14fe3bf3f38b7b950144c2020-11-25T00:12:32ZengHindawi LimitedThe Scientific World Journal1537-744X2013-01-01201310.1155/2013/728414728414Applying Probability Theory for the Quality Assessment of a Wildfire Spread Prediction Framework Based on Genetic AlgorithmsAndrés Cencerrado0Ana Cortés1Tomàs Margalef2Computer Architecture and Operating Systems Department, Autonomous University of Barcelona, Bellaterra, 08193 Barcelona, SpainComputer Architecture and Operating Systems Department, Autonomous University of Barcelona, Bellaterra, 08193 Barcelona, SpainComputer Architecture and Operating Systems Department, Autonomous University of Barcelona, Bellaterra, 08193 Barcelona, SpainThis work presents a framework for assessing how the existing constraints at the time of attending an ongoing forest fire affect simulation results, both in terms of quality (accuracy) obtained and the time needed to make a decision. In the wildfire spread simulation and prediction area, it is essential to properly exploit the computational power offered by new computing advances. For this purpose, we rely on a two-stage prediction process to enhance the quality of traditional predictions, taking advantage of parallel computing. This strategy is based on an adjustment stage which is carried out by a well-known evolutionary technique: Genetic Algorithms. The core of this framework is evaluated according to the probability theory principles. Thus, a strong statistical study is presented and oriented towards the characterization of such an adjustment technique in order to help the operation managers deal with the two aspects previously mentioned: time and quality. The experimental work in this paper is based on a region in Spain which is one of the most prone to forest fires: El Cap de Creus.http://dx.doi.org/10.1155/2013/728414
collection DOAJ
language English
format Article
sources DOAJ
author Andrés Cencerrado
Ana Cortés
Tomàs Margalef
spellingShingle Andrés Cencerrado
Ana Cortés
Tomàs Margalef
Applying Probability Theory for the Quality Assessment of a Wildfire Spread Prediction Framework Based on Genetic Algorithms
The Scientific World Journal
author_facet Andrés Cencerrado
Ana Cortés
Tomàs Margalef
author_sort Andrés Cencerrado
title Applying Probability Theory for the Quality Assessment of a Wildfire Spread Prediction Framework Based on Genetic Algorithms
title_short Applying Probability Theory for the Quality Assessment of a Wildfire Spread Prediction Framework Based on Genetic Algorithms
title_full Applying Probability Theory for the Quality Assessment of a Wildfire Spread Prediction Framework Based on Genetic Algorithms
title_fullStr Applying Probability Theory for the Quality Assessment of a Wildfire Spread Prediction Framework Based on Genetic Algorithms
title_full_unstemmed Applying Probability Theory for the Quality Assessment of a Wildfire Spread Prediction Framework Based on Genetic Algorithms
title_sort applying probability theory for the quality assessment of a wildfire spread prediction framework based on genetic algorithms
publisher Hindawi Limited
series The Scientific World Journal
issn 1537-744X
publishDate 2013-01-01
description This work presents a framework for assessing how the existing constraints at the time of attending an ongoing forest fire affect simulation results, both in terms of quality (accuracy) obtained and the time needed to make a decision. In the wildfire spread simulation and prediction area, it is essential to properly exploit the computational power offered by new computing advances. For this purpose, we rely on a two-stage prediction process to enhance the quality of traditional predictions, taking advantage of parallel computing. This strategy is based on an adjustment stage which is carried out by a well-known evolutionary technique: Genetic Algorithms. The core of this framework is evaluated according to the probability theory principles. Thus, a strong statistical study is presented and oriented towards the characterization of such an adjustment technique in order to help the operation managers deal with the two aspects previously mentioned: time and quality. The experimental work in this paper is based on a region in Spain which is one of the most prone to forest fires: El Cap de Creus.
url http://dx.doi.org/10.1155/2013/728414
work_keys_str_mv AT andrescencerrado applyingprobabilitytheoryforthequalityassessmentofawildfirespreadpredictionframeworkbasedongeneticalgorithms
AT anacortes applyingprobabilitytheoryforthequalityassessmentofawildfirespreadpredictionframeworkbasedongeneticalgorithms
AT tomasmargalef applyingprobabilitytheoryforthequalityassessmentofawildfirespreadpredictionframeworkbasedongeneticalgorithms
_version_ 1725399098976108544

Similar Items