利用双模型深度学习方法对野火蔓延进行超实时预测

IF 6 1区 环境科学与生态学 Q1 ENVIRONMENTAL SCIENCES Journal of Environmental Informatics Pub Date : 2024-01-31 DOI:10.3808/jei.65-79
Y. Z. Li, Z. L. Wang, X. Y. Huang
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引用次数: 0

摘要

在气候变化的驱动下,更加频繁和极端的野火给全球人类带来了更大的威胁。快速蔓延的野火危及荒地与城市交界地区居民的安全。为了减轻野火的危害并促进早期疏散,快速准确地预测野火蔓延对应急响应至关重要。本研究提出了一种新颖的双模型深度学习方法,以实现不同场景下二维野火蔓延的超实时预测。第一个模型利用 U-Net 技术提前 5 小时预测燃烧面积。第二个模型结合 ConvLSTM 层,根据实时更新的输入数据完善预测结果。为评估该方法的有效性,我们将其应用于香港阳光岛,并生成了一个由 210 个案例(12,600 个样本)组成的数值数据库,用于训练深度学习模型。模拟野火蔓延数据库的精细分辨率为 5 米,时间步长为 5 分钟。结果表明,两种模型在数值模拟和人工智能预测之间的总体一致性超过 90%。人工智能的实时野火预报只需几秒钟,比直接模拟快 102-104 倍。我们的研究结果证明了人工智能在提供快速、高分辨率野火蔓延预报方面的潜力,其新颖之处在于利用了两种可协同工作的模型,并可在野火管理的各个阶段加以利用。
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Super Real-Time Forecast of Wildland Fire Spread by A Dual-Model Deep Learning Method
Driven by climate change, more frequent and extreme wildfires have brought a greater threat to humans globally. Fastspreading wildfires endanger the safety of residents in the wildland-urban interface. To mitigate the hazards of wildfires and facilitate early evacuation, a rapid and accurate forecast of wildfire spread is critical in emergency response. This study proposes a novel dualmodel deep learning approach to achieve a super real-time forecast of 2-dimensional wildfire spread in different scenarios. The first model utilizes the U-Net technique to predict the burnt area up to 5 hours in advance. The second model incorporates ConvLSTM layers to refine the forecasted results based on real-time updated input data. To evaluate the effectiveness of this methodology, we applied it to Sunshine Island, Hong Kong, and generated a numerical database consisting of 210 cases (12,600 samples) to train the deep learning models. The simulated wildfire spread database has a fine resolution of 5 m and a time step of 5 minutes. Results show that both models achieve an overall agreement of over 90% between numerical simulation and AI forecast. The real-time wildfire forecasts by AI only take a few seconds, which is 102 ~ 104 times faster than direct simulations. Our findings demonstrate the potential of AI in offering fast and high-resolution forecasts of wildfire spread, and the novel contribution is to leverage two models which can work in tandem and be utilized at various stages of wildfire management.
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来源期刊
Journal of Environmental Informatics
Journal of Environmental Informatics ENVIRONMENTAL SCIENCES-
CiteScore
12.40
自引率
2.90%
发文量
7
审稿时长
24 months
期刊介绍: Journal of Environmental Informatics (JEI) is an international, peer-reviewed, and interdisciplinary publication designed to foster research innovation and discovery on basic science and information technology for addressing various environmental problems. The journal aims to motivate and enhance the integration of science and technology to help develop sustainable solutions that are consensus-oriented, risk-informed, scientifically-based and cost-effective. JEI serves researchers, educators and practitioners who are interested in theoretical and/or applied aspects of environmental science, regardless of disciplinary boundaries. The topics addressed by the journal include: - Planning of energy, environmental and ecological management systems - Simulation, optimization and Environmental decision support - Environmental geomatics - GIS, RS and other spatial information technologies - Informatics for environmental chemistry and biochemistry - Environmental applications of functional materials - Environmental phenomena at atomic, molecular and macromolecular scales - Modeling of chemical, biological and environmental processes - Modeling of biotechnological systems for enhanced pollution mitigation - Computer graphics and visualization for environmental decision support - Artificial intelligence and expert systems for environmental applications - Environmental statistics and risk analysis - Climate modeling, downscaling, impact assessment, and adaptation planning - Other areas of environmental systems science and information technology.
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