Real-Time Wildfire Detection From Space – A Trade-Off Between Sensor Quality, Physical Limitations and Payload Size

Shah, S. B.; Krempel, Lucas; Ernst, Steve H; Mauracher, Florian; Contractor, Steefan

doi:10.5194/isprs-archives-xlii-2-w16-209-2019

Cited by 9 publications

(6 citation statements)

References 12 publications

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“…As of January 2020, over 1100 CubeSats had been successfully launched by various academic institutions and commercial enterprises worldwide. Shah et al [ 90 ] introduced a system comprising a constellation of nanosatellites equipped with multispectral visible-to-infrared cameras and a ground station. This would allow all surface points on the planet to be revisited at least once per hour.…”

Section: Analysis Of Wildfire Smoke Detection Based On Various Systemsmentioning

confidence: 99%

A Wildfire Smoke Detection System Using Unmanned Aerial Vehicle Images Based on the Optimized YOLOv5

Mukhiddinov

Abdusalomov

2022

Sensors

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Wildfire is one of the most significant dangers and the most serious natural catastrophe, endangering forest resources, animal life, and the human economy. Recent years have witnessed a rise in wildfire incidents. The two main factors are persistent human interference with the natural environment and global warming. Early detection of fire ignition from initial smoke can help firefighters react to such blazes before they become difficult to handle. Previous deep-learning approaches for wildfire smoke detection have been hampered by small or untrustworthy datasets, making it challenging to extrapolate the performances to real-world scenarios. In this study, we propose an early wildfire smoke detection system using unmanned aerial vehicle (UAV) images based on an improved YOLOv5. First, we curated a 6000-wildfire image dataset using existing UAV images. Second, we optimized the anchor box clustering using the K-mean++ technique to reduce classification errors. Then, we improved the network’s backbone using a spatial pyramid pooling fast-plus layer to concentrate small-sized wildfire smoke regions. Third, a bidirectional feature pyramid network was applied to obtain a more accessible and faster multi-scale feature fusion. Finally, network pruning and transfer learning approaches were implemented to refine the network architecture and detection speed, and correctly identify small-scale wildfire smoke areas. The experimental results proved that the proposed method achieved an average precision of 73.6% and outperformed other one- and two-stage object detectors on a custom image dataset.

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Section: Analysis Of Wildfire Smoke Detection Based On Various Systemsmentioning

confidence: 99%

A Wildfire Smoke Detection System Using Unmanned Aerial Vehicle Images Based on the Optimized YOLOv5

Mukhiddinov

Abdusalomov

2022

Sensors

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“…With satellites, it is possible to detect extensive wildfires using thermal infrared and high-temperature-sensitive short-wave infrared channels [25]. Due to their low cost and large-area repetitive coverage, satellite devices are useful in near-real-time fire detection, monitoring, and assessment of blazed areas [49]. However, despite exhibiting a high spatial resolution, sun-synchronous satellites have a low time resolution therefore making it challenging to detect wildfires in real time.…”

Section: Introductionmentioning

confidence: 99%

A Synergistic Approach to Wildfire Prevention and Management using AI, Machine Learning, and 5G Technology in the United States

C. Stanley,

Alexander,

O. Austine

2024

Artificial Intelligence and Big Data

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In recent years, wildfires have emerged as a global environmental crisis, causing significant damage to ecosystems, and contributing to climate change. Wildfire management methods involve prevention, response, and recovery efforts. Despite advancements in detection methods, the increasing frequency of wildfires necessitates innovative solutions for early detection and efficient management. This study explores proactive approaches to detect and manage wildfires in the United States by leveraging Artificial Intelligence (AI), Machine Learning (ML), and 5G technology. The specific objective of this research covers proactive detection and prevention of wildfires using advanced technology; Active monitoring and mapping with remote sensing and signaling leveraging on 5G technology; and Advanced response mechanisms to wildfire using drones and IOT devices. This study was based on secondary data collected from government databases and analyzed using descriptive statistics. In addition, past publications were reviewed through content analysis, and narrative synthesis was used to present the observations from various studies. The results showed that developing new technology presents an opportunity to detect and manage wildfires proactively. This would save a lot of lives and prevent huge economic loss that is attributed to wildfire outbreaks and spread. Advanced technology can be used in several ways to help in the proactive detection and management of wildfires. This includes the development of the use of AI-enabled remote sensing and signaling devices and leveraging 5G technology for active monitoring and mapping of wildfires. In addition, super intelligent drones and IOT devices can be used for safer responses to wildfires. This forms the core of the recommendation to the fire Management Agencies and the government.

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“…This method achieves real-time detection of FMC through satellite remote sensing, providing an effective means for early wildfire warning. Shah et al [3] used CubeSats satellites with a modular and cost-effective architecture in Low Earth Orbit (LEO), achieved early detection of wildfires within 30 min using multispectral visible to infrared cameras. Shaik et al [4] classified fuel types using high-resolution images from PRecursore IperSpettrale della Missione Applicativa (PRISMA), demonstrating the effectiveness of the Scott/Burgan fuel model system through ground assessments, satellite measurements, and simulated concentration displays of summer data.…”

Section: Introductionmentioning

confidence: 99%

Comparison and Analysis of Three MobileNet-Based Models for Wildfire Detection

Du,

Li,

Noto

2024

JAIT

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The dynamic equilibrium of ecosystems can be maintained through controlled burning, but excessive wildfires can lead to severe consequences. Therefore, the use of Internet of Things (IoT) devices equipped with deep image processing models for wildfire detection has recently become a trend. Conventional deep image processing models suffer from accuracy issues and large model sizes, limiting their applicability on small IoT devices. To address this challenge, we utilized lightweight deep image processing models such as the MobileNet series to train a wildfire database. Furthermore, we evaluated three different versions of MobileNet (V2, V3 Large, and V3 Small) using a crossentropy loss function to compare their accuracy and training times. Through data analysis, recommendations for deploying MobileNet models on IoT devices are provided. The results indicate that the ranking of MobileNet's accuracy from highest to lowest is V2, V3 Large, and V3 Small; the ranking of loss values from lowest to highest is V2, V3 Large, and V3 Small; and the ranking of training times from fastest to slowest is V3 Large, V2, and V3 Small.

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Real-Time Wildfire Detection From Space – A Trade-Off Between Sensor Quality, Physical Limitations and Payload Size

Cited by 9 publications

References 12 publications

A Wildfire Smoke Detection System Using Unmanned Aerial Vehicle Images Based on the Optimized YOLOv5

A Wildfire Smoke Detection System Using Unmanned Aerial Vehicle Images Based on the Optimized YOLOv5

A Synergistic Approach to Wildfire Prevention and Management using AI, Machine Learning, and 5G Technology in the United States

Comparison and Analysis of Three MobileNet-Based Models for Wildfire Detection

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