Queue-aware computation offloading for UAV-assisted edge computing in wind farm routine inspection

Integration of unmanned aerial vehicles (UAVs) and edge computing into the wind farm routine inspection provides a promising approach to enhancing inspection effectiveness and decreasing operation maintenance costs. In light of the finite battery power and computational capacity of UAVs, a dynamic q...

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Bibliographic Details
Published in:Journal of renewable and sustainable energy 2023-11, Vol.15 (6)
Main Authors: Han, Yinghua, Xu, Qinqin, Zhao, Qiang, Si, Fangyuan
Format: Article
Language:English
Subjects:
Algorithms
Computation offloading
Edge computing
Energy consumption
Inspection effectiveness
Maintenance costs
Optimization
Queueing
Queues
Resource allocation
Servers
Unmanned aerial vehicles
Wind farms
Wind power
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Summary:Integration of unmanned aerial vehicles (UAVs) and edge computing into the wind farm routine inspection provides a promising approach to enhancing inspection effectiveness and decreasing operation maintenance costs. In light of the finite battery power and computational capacity of UAVs, a dynamic queue-aware UAV-assisted edge computing inspection wind farm framework is investigated with the goal of minimizing the long-term energy consumption of UAVs. The Lyapunov optimization theory is utilized to decouple the long-term stochastic optimization problem into four short-term deterministic subproblems, including the task splitting, the UAV-side computing resource allocation, the task offloading, and the edge server-side computing resource allocation. Furthermore, a Lyapunov optimization-based dynamic queue-aware computation offloading algorithm (LODQCO) is presented to optimize task offloading and resource allocation jointly. The optimal UAV-side computing resource is determined by a closed form formula, and then the optimal task offloading decision is tackled by applying the classical interior point method. Finally, the edge server-side computing resource is addressed via a linear optimization CPLEX solver. Based on simulation results, LODQCO is superior to the benchmark algorithms with respect to the energy consumption, queue backlogs, and queuing delays.
ISSN:1941-7012
1941-7012
DOI:10.1063/5.0152767