TY - JOUR
T1 - Wildfire Predictions: Determining Reliable Models using Fused Dataset
AU - Naganathan, Hariharan
AU - Seshasayee, Sudarshan P.
AU - Kim, Jonghoon
AU - Chong, Wai K.
AU - Chou, Jui-Sheng
N1 - Kim, J., Naganathan, H., Seshasayee, S.P., Chong, W.K., Chou, J.S. (2016). Wildfire Predictions: Determining Reliable Models using Fused Dataset. Global Journal of Computer Science and Technology: C Software & Data Engineering, 16(4), 28-40. https://globaljournals.org/GJCST_Volume16/5-Wildfire-Predictions-Determining.pdf
PY - 2016/1/1
Y1 - 2016/1/1
N2 - Wildfires are a major environmental hazard that causes fatalities greater than structural fire and other disasters. Computerized models have increased the possibilities of predictions that enhanced the firefighting capabilities in U.S. While predictive models are faster and accurate, it is still important to identify the right model for the data type analyzed. The paper aims at understanding the reliability of three predictive methods using fused dataset. Performances of these methods (Support Vector Machine, K-Nearest Neighbors, and decision tree models) are evaluated using binary and multiclass classifications that predict wildfire occurrence and its severity. Data extracted from meteorological database, and U.S fire database are utilized to understand the accuracy of these models that enhances the discussion on using right model for dataset based on their size. The findings of the paper include SVM as the best optimum models for binary and multiclass classifications on the selected fused dataset.
AB - Wildfires are a major environmental hazard that causes fatalities greater than structural fire and other disasters. Computerized models have increased the possibilities of predictions that enhanced the firefighting capabilities in U.S. While predictive models are faster and accurate, it is still important to identify the right model for the data type analyzed. The paper aims at understanding the reliability of three predictive methods using fused dataset. Performances of these methods (Support Vector Machine, K-Nearest Neighbors, and decision tree models) are evaluated using binary and multiclass classifications that predict wildfire occurrence and its severity. Data extracted from meteorological database, and U.S fire database are utilized to understand the accuracy of these models that enhances the discussion on using right model for dataset based on their size. The findings of the paper include SVM as the best optimum models for binary and multiclass classifications on the selected fused dataset.
KW - binary and multiclass classifiers
KW - decision tree stumps
KW - forest fire
KW - k-fold cross-validation
KW - k-nearest neighbor
KW - support vector machines
M3 - Article
SN - 0975-4350
VL - 16
SP - 28
EP - 40
JO - Global Journal of Computer Science and Technology: C Software & Data Engineering
JF - Global Journal of Computer Science and Technology: C Software & Data Engineering
IS - 4
ER -