Shubhangi Chaturvedi;Poornima Singh Thakur;Pritee Khanna;Aparajita Ojha;Yongze Song;Joseph L. Awange
{"title":"基于卫星图像的多关注交错网络监测与早期野火烟雾探测","authors":"Shubhangi Chaturvedi;Poornima Singh Thakur;Pritee Khanna;Aparajita Ojha;Yongze Song;Joseph L. Awange","doi":"10.1109/TII.2025.3528549","DOIUrl":null,"url":null,"abstract":"The increasing frequency and intensity of wildfires in recent years have not only devastated forest ecosystems, but have also caused a significant economic burden. According to a World Economic Forum report, annual expenditures to combat wildfire hazards is estimated to be more than <inline-formula><tex-math>$ {\\$} 50$</tex-math></inline-formula> billion. This calls for advanced solutions, such as remote sensing surveillance and the use of artificial intelligence for wildfire management. In recent years, several vision-based artificial intelligence techniques have been proposed for fire–smoke image classification that utilise convolutional neural networks. However, challenges persist, particularly in identifying fire–smoke under complex atmospheric conditions. In this article, we introduce a novel multiattention network that interlaces the vision transformer and convolutional neural network to detect fire–smoke in diverse conditions, including clouds, fog, hurricanes, storms, snow, and normal weather. The proposed model not only outperforms eight state-of-the-art fire–smoke image classification methods, but also reduces false alarms by 30% on IIITDMJ <inline-formula><tex-math>$\\_$</tex-math></inline-formula> Smoke dataset and by 6% on UTSC <inline-formula><tex-math>$\\_$</tex-math></inline-formula> SmokeRS dataset. The model also efficiently identifies even tiny occurrence of smoke covering as little as 2% area of an image. The model has also been tested on industrial chimney smoke images and outdoor video fire–smoke scenes. Furthermore, the lightweight architecture of the model with only 0.7 million parameters and 0.2 billion floating point operations per second makes it suitable for deployment on Internet of Things-based forest and industrial surveillance systems.","PeriodicalId":13301,"journal":{"name":"IEEE Transactions on Industrial Informatics","volume":"21 5","pages":"3806-3815"},"PeriodicalIF":9.8000,"publicationDate":"2025-02-13","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Satellite Image-Based Surveillance and Early Wildfire Smoke Detection Using a Multiattention Interlaced Network\",\"authors\":\"Shubhangi Chaturvedi;Poornima Singh Thakur;Pritee Khanna;Aparajita Ojha;Yongze Song;Joseph L. Awange\",\"doi\":\"10.1109/TII.2025.3528549\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"The increasing frequency and intensity of wildfires in recent years have not only devastated forest ecosystems, but have also caused a significant economic burden. According to a World Economic Forum report, annual expenditures to combat wildfire hazards is estimated to be more than <inline-formula><tex-math>$ {\\\\$} 50$</tex-math></inline-formula> billion. This calls for advanced solutions, such as remote sensing surveillance and the use of artificial intelligence for wildfire management. In recent years, several vision-based artificial intelligence techniques have been proposed for fire–smoke image classification that utilise convolutional neural networks. However, challenges persist, particularly in identifying fire–smoke under complex atmospheric conditions. In this article, we introduce a novel multiattention network that interlaces the vision transformer and convolutional neural network to detect fire–smoke in diverse conditions, including clouds, fog, hurricanes, storms, snow, and normal weather. The proposed model not only outperforms eight state-of-the-art fire–smoke image classification methods, but also reduces false alarms by 30% on IIITDMJ <inline-formula><tex-math>$\\\\_$</tex-math></inline-formula> Smoke dataset and by 6% on UTSC <inline-formula><tex-math>$\\\\_$</tex-math></inline-formula> SmokeRS dataset. The model also efficiently identifies even tiny occurrence of smoke covering as little as 2% area of an image. The model has also been tested on industrial chimney smoke images and outdoor video fire–smoke scenes. 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Satellite Image-Based Surveillance and Early Wildfire Smoke Detection Using a Multiattention Interlaced Network
The increasing frequency and intensity of wildfires in recent years have not only devastated forest ecosystems, but have also caused a significant economic burden. According to a World Economic Forum report, annual expenditures to combat wildfire hazards is estimated to be more than $ {\$} 50$ billion. This calls for advanced solutions, such as remote sensing surveillance and the use of artificial intelligence for wildfire management. In recent years, several vision-based artificial intelligence techniques have been proposed for fire–smoke image classification that utilise convolutional neural networks. However, challenges persist, particularly in identifying fire–smoke under complex atmospheric conditions. In this article, we introduce a novel multiattention network that interlaces the vision transformer and convolutional neural network to detect fire–smoke in diverse conditions, including clouds, fog, hurricanes, storms, snow, and normal weather. The proposed model not only outperforms eight state-of-the-art fire–smoke image classification methods, but also reduces false alarms by 30% on IIITDMJ $\_$ Smoke dataset and by 6% on UTSC $\_$ SmokeRS dataset. The model also efficiently identifies even tiny occurrence of smoke covering as little as 2% area of an image. The model has also been tested on industrial chimney smoke images and outdoor video fire–smoke scenes. Furthermore, the lightweight architecture of the model with only 0.7 million parameters and 0.2 billion floating point operations per second makes it suitable for deployment on Internet of Things-based forest and industrial surveillance systems.
期刊介绍:
The IEEE Transactions on Industrial Informatics is a multidisciplinary journal dedicated to publishing technical papers that connect theory with practical applications of informatics in industrial settings. It focuses on the utilization of information in intelligent, distributed, and agile industrial automation and control systems. The scope includes topics such as knowledge-based and AI-enhanced automation, intelligent computer control systems, flexible and collaborative manufacturing, industrial informatics in software-defined vehicles and robotics, computer vision, industrial cyber-physical and industrial IoT systems, real-time and networked embedded systems, security in industrial processes, industrial communications, systems interoperability, and human-machine interaction.