A review of a new generation of wildfire–atmosphere modeling

Bakhshaii, Atoossa; Johnson, Edward A.

doi:10.1139/cjfr-2018-0138

Cited by 68 publications

(46 citation statements)

References 49 publications

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“…Our approach exemplifies how scientific computing can leverage machine learning and hardware accelerators to improve simulations without sacrificing accuracy or generalization. machine learning | turbulence | computational physics | nonlinear partial differential equations S imulation of complex physical systems described by nonlinear partial differential equations (PDEs) is central to engineering and physical science, with applications ranging from weather (1,2) and climate (3,4) and engineering design of vehicles or engines (5) to wildfires (6) and plasma physics (7). Despite a direct link between the equations of motion and the basic laws of physics, it is impossible to carry out direct numerical simulations at the scale required for these important problems.…”

mentioning

confidence: 99%

“…Simulation of complex physical systems described by nonlinear partial differential equations (PDEs) is central to engineering and physical science, with applications ranging from weather ( 1 , 2 ) and climate ( 3 , 4 ) and engineering design of vehicles or engines ( 5 ) to wildfires ( 6 ) and plasma physics ( 7 ). Despite a direct link between the equations of motion and the basic laws of physics, it is impossible to carry out direct numerical simulations at the scale required for these important problems.…”

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confidence: 99%

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Machine learning–accelerated computational fluid dynamics

Kochkov

Smith

Alieva

et al. 2021

Proc. Natl. Acad. Sci. U.S.A.

602

254

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Numerical simulation of fluids plays an essential role in modeling many physical phenomena, such as weather, climate, aerodynamics, and plasma physics. Fluids are well described by the Navier–Stokes equations, but solving these equations at scale remains daunting, limited by the computational cost of resolving the smallest spatiotemporal features. This leads to unfavorable trade-offs between accuracy and tractability. Here we use end-to-end deep learning to improve approximations inside computational fluid dynamics for modeling two-dimensional turbulent flows. For both direct numerical simulation of turbulence and large-eddy simulation, our results are as accurate as baseline solvers with 8 to 10× finer resolution in each spatial dimension, resulting in 40- to 80-fold computational speedups. Our method remains stable during long simulations and generalizes to forcing functions and Reynolds numbers outside of the flows where it is trained, in contrast to black-box machine-learning approaches. Our approach exemplifies how scientific computing can leverage machine learning and hardware accelerators to improve simulations without sacrificing accuracy or generalization.

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mentioning

confidence: 99%

mentioning

confidence: 99%

Machine learning–accelerated computational fluid dynamics

Kochkov

Smith

Alieva

et al. 2021

Proc. Natl. Acad. Sci. U.S.A.

602

254

View full text Add to dashboard Cite

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“…He studied the rate of fire movement, predicted flame length, energy, and ecological impact, and concluded that Canadian models, including RedAPP and CanFIRE provide more accurate predictions than BehavePlus. Similarly, many tools exist for fire, and smoke models, which are crucial in decision making and planning to tackle the forest or a wild-land fire [74][75][76][77]. A lot of research has been done in the last two decades, especially after the increase of computation power during the last few years [77][78][79][80].…”

Section: Scope Of ML Algorithms In Forest Fire Management Frame-workmentioning

confidence: 99%

“…Similarly, many tools exist for fire, and smoke models, which are crucial in decision making and planning to tackle the forest or a wild-land fire [74][75][76][77]. A lot of research has been done in the last two decades, especially after the increase of computation power during the last few years [77][78][79][80]. Satellite active fire data such as Visible Infrared Imager Radiometer Suite (VIIRS) [81], moderate-resolution imaging spectro-radiometer (MODIS) [82] etc., can be vention and fighting [62,63].…”

Section: Scope Of ML Algorithms In Forest Fire Management Frame-workmentioning

confidence: 99%

Role of Machine Learning Algorithms in Forest Fire Management: A Literature Review

Arif¹,

K²,

A³

et al. 2021

J Robotics Autom

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Forest fire disasters are recently getting lots of attention due to climate change globally. Globally, climate changes are rapidly changing the fire patterns on Earth. Effective fire management requires accurate information about the fire occurrence, its spread, and impact on the environment. Prediction of fire activities in the forest guides the authorities to make optimal, efficient, and sound decisions in fire management. This paper aims to summarize recent trends in the forest fire events prediction, detection, spread rate, and mapping of the burned areas. Furthermore, fire emissions in terms of smoke also put the Earth's public health and ecological system at greater risk. Hence, future policymaking can be more accurate in saving billions of dollars, improving the healthy environment and ecological cycle for the inhabitants of this Earth. This paper provides a comprehensive review of the usage of different machine learning algorithms in forest fire or wildfire management. Furthermore, we have identified some potential areas where new technologies and data can help better fire management decision making.

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“…In the past few decades, wildland and wildland-urban interface (WUI) fires have received substantial attention due to their destructive nature and extensive cost to lives and property [1][2][3]. A large body of literature can be found on the subject, as seen in various review articles [2,4,5]. Due to the complex nature of fire, limited computing resources, and the needs of planners and first responders, most models of wildfires have historically relied on simplified field-tested rules and correlations.…”

Section: Introductionmentioning

confidence: 99%

A Multi-Fidelity Framework for Wildland Fire Behavior Simulations over Complex Terrain

et al. 2021

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A method for the large-eddy simulation (LES) of wildfire spread over complex terrain is presented. In this scheme, a cut-cell immersed boundary method (CC-IBM) is used to render the complex terrain, defined by a tessellation, on a rectilinear Cartesian grid. Discretization of scalar transport equations for chemical species is done via a finite volume scheme on cut-cells defined by the intersection of the terrain geometry and the Cartesian cells. Momentum transport and heat transfer close to the immersed terrain are handled using dynamic wall models and a direct forcing immersed boundary method. A new “open” convective inflow/outflow method for specifying atmospheric wind boundary conditions is presented. Additionally, three basic approaches have been explored to model fire spread: (1) Representing the vegetation as a collection of Lagrangian particles, (2) representing the vegetation as a semi-porous boundary, and (3) representing the fire spread using a level set method, in which the fire spreads as a function of terrain slope, vegetation type, and wind speed. Several test and validation cases are reported to demonstrate the capabilities of this novel wildfire simulation methodology.

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A review of a new generation of wildfire–atmosphere modeling

Cited by 68 publications

References 49 publications

Machine learning–accelerated computational fluid dynamics

Machine learning–accelerated computational fluid dynamics

Role of Machine Learning Algorithms in Forest Fire Management: A Literature Review

A Multi-Fidelity Framework for Wildland Fire Behavior Simulations over Complex Terrain

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