Joint Optimization of Caching, Computing and Trajectory Planning in Aerial Mobile Edge Computing Networks: A MADDPG Approach

Joint Optimization of Caching, Computing and Trajectory Planning in Aerial Mobile Edge Computing Networks: A MADDPG Approach

The 6G network is expected to accommodate a wide array of connected devices, supporting diverse services from any location at any time. In this paper, we introduce an aerial Mobile Edge Computing (MEC) framework composed of High-Altitude Platforms (HAPs) and low-altitude Unmanned Aerial Vehicles (UA...

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Bibliographic Details
Published in:IEEE internet of things journal p. 1
Main Authors: Sun, Haifeng, Zhou, Yuqiang, Zhang, Hui, Ale, Laha, Dai, Hongning, Zhang, Ning
Format: Journal Article
Language:English
Published: IEEE 09-09-2024
Subjects:
Aerial Access Networks
Autonomous aerial vehicles
Computational modeling
Containers
Internet of Things
joint optimization
MADDPG
Mobile Edge Computing
Optimization
Servers
task offloading
Wireless communication
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Summary:The 6G network is expected to accommodate a wide array of connected devices, supporting diverse services from any location at any time. In this paper, we introduce an aerial Mobile Edge Computing (MEC) framework composed of High-Altitude Platforms (HAPs) and low-altitude Unmanned Aerial Vehicles (UAVs), to cater to computing offloading for Internet of Things (IoT) devices, particularly in rural/remote areas or disaster zones. The framework accommodates various types of tasks, each computed by the corresponding Docker container. The objective is to achieve optimal workload fairness for UAVs while simultaneously minimizing the weighted processing costs among IoT devices in terms of task computation latency and energy consumption over the long term. This is achieved by jointly optimizing the flight trajectories and Docker image caching decisions of the UAVs with limited storage capacities, alongside ensuring service fairness for IoT devices. We tailor a Multi-Agent Deep Deterministic Policy Gradient (MADDPG)-based approach to solve the long-term joint optimization problem, normalizing continuous actions and sampling discrete actions by generalizing the Gumbel-Softmax reparameterization trick. Experimental results indicate that our approach significantly outperforms benchmark schemes in terms of processing delay, energy consumption, and fairness.
ISSN:2327-4662
2327-4662
DOI:10.1109/JIOT.2024.3456846