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Main Authors: Bolt, Andrew, Huston, Carolyn, Kuhnert, Petra, Dabrowski, Joel Janek, Hilton, James, Sanderson, Conrad
Format: Preprint
Published: 2022
Subjects:
Online Access:https://arxiv.org/abs/2206.08523
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author Bolt, Andrew
Huston, Carolyn
Kuhnert, Petra
Dabrowski, Joel Janek
Hilton, James
Sanderson, Conrad
author_facet Bolt, Andrew
Huston, Carolyn
Kuhnert, Petra
Dabrowski, Joel Janek
Hilton, James
Sanderson, Conrad
contents Computational simulations of wildfire spread typically employ empirical rate-of-spread calculations under various conditions (such as terrain, fuel type, weather). Small perturbations in conditions can often lead to significant changes in fire spread (such as speed and direction), necessitating a computationally expensive large set of simulations to quantify uncertainty. Model emulation seeks alternative representations of physical models using machine learning, aiming to provide more efficient and/or simplified surrogate models. We propose a dedicated spatio-temporal neural network based framework for model emulation, able to capture the complex behaviour of fire spread models. The proposed approach can approximate forecasts at fine spatial and temporal resolutions that are often challenging for neural network based approaches. Furthermore, the proposed approach is robust even with small training sets, due to novel data augmentation methods. Empirical experiments show good agreement between simulated and emulated firefronts, with an average Jaccard score of 0.76.
format Preprint
id arxiv_https___arxiv_org_abs_2206_08523
institution arXiv
publishDate 2022
record_format arxiv
spellingShingle A Spatio-Temporal Neural Network Forecasting Approach for Emulation of Firefront Models
Bolt, Andrew
Huston, Carolyn
Kuhnert, Petra
Dabrowski, Joel Janek
Hilton, James
Sanderson, Conrad
Machine Learning
Computational simulations of wildfire spread typically employ empirical rate-of-spread calculations under various conditions (such as terrain, fuel type, weather). Small perturbations in conditions can often lead to significant changes in fire spread (such as speed and direction), necessitating a computationally expensive large set of simulations to quantify uncertainty. Model emulation seeks alternative representations of physical models using machine learning, aiming to provide more efficient and/or simplified surrogate models. We propose a dedicated spatio-temporal neural network based framework for model emulation, able to capture the complex behaviour of fire spread models. The proposed approach can approximate forecasts at fine spatial and temporal resolutions that are often challenging for neural network based approaches. Furthermore, the proposed approach is robust even with small training sets, due to novel data augmentation methods. Empirical experiments show good agreement between simulated and emulated firefronts, with an average Jaccard score of 0.76.
title A Spatio-Temporal Neural Network Forecasting Approach for Emulation of Firefront Models
topic Machine Learning
url https://arxiv.org/abs/2206.08523