Nature-Inspired Drone Swarming for Wildfires Suppression Considering Distributed Fire Spots and Energy Consumption
Wildfires are among the biggest problems faced worldwide. They are increasing in severity and frequency, causing economic losses, human death, and significant environmental damage. Environmental factors, such as wind and large forest areas, contribute to the fire spreading over multiple fire spots,...
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my.uniten.dspace-346082024-10-14T11:21:04Z Nature-Inspired Drone Swarming for Wildfires Suppression Considering Distributed Fire Spots and Energy Consumption Alsammak I.L.H. Mahmoud M.A. Gunasekaran S.S. Ahmed A.N. Alkilabi M. 57220190775 55247787300 55652730500 57214837520 57191252149 Random walk algorithm stigmergy swarm intelligence UAVs wildfires suppression Agricultural robots Antennas Drones Energy utilization Fires High resolution transmission electron microscopy Intelligent robots Job analysis Losses Numerical methods Particle swarm optimization (PSO) Random processes Swarm intelligence Aerial vehicle Classification algorithm Particle swarm Particle swarm optimization Random walk algorithms Stigmergy Swarm optimization Task analysis Unmanned aerial vehicle Wildfire suppression Forestry Wildfires are among the biggest problems faced worldwide. They are increasing in severity and frequency, causing economic losses, human death, and significant environmental damage. Environmental factors, such as wind and large forest areas, contribute to the fire spreading over multiple fire spots, all of which grow continuously, making fire suppression extremely difficult. Therefore, fire spots should be coverage simultaneously to contain the spread and prevent coalescence. Therefore, this study presents a new model based on the principles of nature-inspired metaheuristics that uses Swarm Intelligence (SI) to test the effectiveness of using an autonomous and decentralized behaviour for a swarm of Unmanned Aerial Vehicles (UAVs) or drones to detect all distributed fire spots and extinguishing them cooperatively. To achieve this goal, we used the improved random walk algorithm to explore the distributed fire spots and a self-coordination mechanism based on the stigmergy as an indirect communication between the swarm drones, taking into account the collision avoidance factor, the amount of extinguishing fluid, and the flight range of the drones. Numerical analysis and extensive simulations were performed to investigate the behaviour of the proposed methods and analyze their performance in terms of the area-coverage rate and total energy required by the drone swarm to complete the task. Our quantitative tests show that the improved model has the best coverage (95.3%, 84.3% and 65.8%, respectively) compared to two other methods Levy Flight (LF) algorithm and Particle Swarm Optimization (PSO), which use the same initial parameter values. The simulation results show that the proposed model performs better than its competitors and saves energy, especially in more complicated situations. � 2013 IEEE. Final 2024-10-14T03:21:04Z 2024-10-14T03:21:04Z 2023 Article 10.1109/ACCESS.2023.3279416 2-s2.0-85161054187 https://www.scopus.com/inward/record.uri?eid=2-s2.0-85161054187&doi=10.1109%2fACCESS.2023.3279416&partnerID=40&md5=600446ca503df267c880c46ddaff1ed7 https://irepository.uniten.edu.my/handle/123456789/34608 11 50962 50983 All Open Access Gold Open Access Institute of Electrical and Electronics Engineers Inc. Scopus |
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Random walk algorithm stigmergy swarm intelligence UAVs wildfires suppression Agricultural robots Antennas Drones Energy utilization Fires High resolution transmission electron microscopy Intelligent robots Job analysis Losses Numerical methods Particle swarm optimization (PSO) Random processes Swarm intelligence Aerial vehicle Classification algorithm Particle swarm Particle swarm optimization Random walk algorithms Stigmergy Swarm optimization Task analysis Unmanned aerial vehicle Wildfire suppression Forestry |
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Random walk algorithm stigmergy swarm intelligence UAVs wildfires suppression Agricultural robots Antennas Drones Energy utilization Fires High resolution transmission electron microscopy Intelligent robots Job analysis Losses Numerical methods Particle swarm optimization (PSO) Random processes Swarm intelligence Aerial vehicle Classification algorithm Particle swarm Particle swarm optimization Random walk algorithms Stigmergy Swarm optimization Task analysis Unmanned aerial vehicle Wildfire suppression Forestry Alsammak I.L.H. Mahmoud M.A. Gunasekaran S.S. Ahmed A.N. Alkilabi M. Nature-Inspired Drone Swarming for Wildfires Suppression Considering Distributed Fire Spots and Energy Consumption |
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Wildfires are among the biggest problems faced worldwide. They are increasing in severity and frequency, causing economic losses, human death, and significant environmental damage. Environmental factors, such as wind and large forest areas, contribute to the fire spreading over multiple fire spots, all of which grow continuously, making fire suppression extremely difficult. Therefore, fire spots should be coverage simultaneously to contain the spread and prevent coalescence. Therefore, this study presents a new model based on the principles of nature-inspired metaheuristics that uses Swarm Intelligence (SI) to test the effectiveness of using an autonomous and decentralized behaviour for a swarm of Unmanned Aerial Vehicles (UAVs) or drones to detect all distributed fire spots and extinguishing them cooperatively. To achieve this goal, we used the improved random walk algorithm to explore the distributed fire spots and a self-coordination mechanism based on the stigmergy as an indirect communication between the swarm drones, taking into account the collision avoidance factor, the amount of extinguishing fluid, and the flight range of the drones. Numerical analysis and extensive simulations were performed to investigate the behaviour of the proposed methods and analyze their performance in terms of the area-coverage rate and total energy required by the drone swarm to complete the task. Our quantitative tests show that the improved model has the best coverage (95.3%, 84.3% and 65.8%, respectively) compared to two other methods Levy Flight (LF) algorithm and Particle Swarm Optimization (PSO), which use the same initial parameter values. The simulation results show that the proposed model performs better than its competitors and saves energy, especially in more complicated situations. � 2013 IEEE. |
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57220190775 |
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57220190775 Alsammak I.L.H. Mahmoud M.A. Gunasekaran S.S. Ahmed A.N. Alkilabi M. |
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Article |
author |
Alsammak I.L.H. Mahmoud M.A. Gunasekaran S.S. Ahmed A.N. Alkilabi M. |
author_sort |
Alsammak I.L.H. |
title |
Nature-Inspired Drone Swarming for Wildfires Suppression Considering Distributed Fire Spots and Energy Consumption |
title_short |
Nature-Inspired Drone Swarming for Wildfires Suppression Considering Distributed Fire Spots and Energy Consumption |
title_full |
Nature-Inspired Drone Swarming for Wildfires Suppression Considering Distributed Fire Spots and Energy Consumption |
title_fullStr |
Nature-Inspired Drone Swarming for Wildfires Suppression Considering Distributed Fire Spots and Energy Consumption |
title_full_unstemmed |
Nature-Inspired Drone Swarming for Wildfires Suppression Considering Distributed Fire Spots and Energy Consumption |
title_sort |
nature-inspired drone swarming for wildfires suppression considering distributed fire spots and energy consumption |
publisher |
Institute of Electrical and Electronics Engineers Inc. |
publishDate |
2024 |
_version_ |
1814061129456943104 |
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13.222552 |