Abstract
The environmental challenges the world faces have never been greater or more complex. Global areas that are covered by forests and urban woodlands are threatened by large-scale forest fires that have increased dramatically during the last decades in Europe and worldwide, in terms of both frequency and magnitude. To this end, rapid advances in remote sensing systems including ground-based, unmanned aerial vehicle-based and satellite-based systems have been adopted for effective forest fire surveillance. In this paper, the recently introduced 360-degree sensor cameras are proposed for early fire detection, making it possible to obtain unlimited field of view captures which reduce the number of required sensors and the computational cost and make the systems more efficient. More specifically, once optical 360-degree raw data are obtained using an RGB 360-degree camera mounted on an unmanned aerial vehicle, we convert the equirectangular projection format images to stereographic images. Then, two DeepLab V3+ networks are applied to perform flame and smoke segmentation, respectively. Subsequently, a novel post-validation adaptive method is proposed exploiting the environmental appearance of each test image and reducing the false-positive rates. For evaluating the performance of the proposed system, a dataset, namely the “Fire detection 360-degree dataset”, consisting of 150 unlimited field of view images that contain both synthetic and real fire, was created. Experimental results demonstrate the great potential of the proposed system, which has achieved an F-score fire detection rate equal to 94.6%, hence reducing the number of required sensors. This indicates that the proposed method could significantly contribute to early fire detection.
Highlights
The increasing occurrence of large-scale forest fires in modern society significantly impacts society and communities in terms of remarkable losses in human lives, infrastructures and properties [1]
We propose a novel early fire detection remote sensing system using aerial 360-degree digital cameras in an operationally and time efficient manner, aiming to overcome the limited field of view of state-of-the-art systems and human-controlled specified data capturing
The code of the proposed structure was implemented in Matlab and all calculations were performed on a 12 GB GPU
Summary
The increasing occurrence of large-scale forest fires in modern society significantly impacts society and communities in terms of remarkable losses in human lives, infrastructures and properties [1]. Wildfires impact environment and climate change, increasing the released quantity levels of CO2, soot and aerosols and damaging the forests that would remove CO2 from the air This results in extremely dry conditions, increasing the risk of wildfires. Forest fires lead to runoff generation and to major changes to the soil infiltration [2] To this end, computer-based early fire warning systems that incorporate remote sensing technologies have attracted particular attention in the last decade. Computer-based early fire warning systems that incorporate remote sensing technologies have attracted particular attention in the last decade These early detection systems use individual or networks of ground sensors, unmanned aerial vehicles (UAVs) and satellite-based systems consisting of active or passive sensors. Most of the active sensors’ systems operate in the microwave portion of the electromagnetic spectrum, and passive systems operate in the visible, infrared and microwave portions of the electromagnetic spectrum [5,6,7,8,9]
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