Combining graph neural network with deep reinforcement learning for resource allocation in computing force networks

Combining graph neural network with deep reinforcement learning for resource allocation in computing force networks

Fueled by the explosive growth of ultra-low-latency and real-time applications with specific computing and network performance requirements, the computing force network (CFN) has become a hot research subject. The primary CFN challenge is to leverage network resources and computing resources. Althou...

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Veröffentlicht in:Frontiers of information technology & electronic engineering 2024-05, Vol.25 (5), p.701-712
Hauptverfasser: Han, Xueying, Xie, Mingxi, Yu, Ke, Huang, Xiaohong, Du, Zongpeng, Yao, Huijuan
Format: Artikel
Sprache:eng
Schlagworte:
Bandwidths
Cloud computing
Communications Engineering
Communications networks
Communications traffic
Computation
Computer Hardware
Computer Science
Computer Systems Organization and Communication Networks
Deep learning
Edge computing
Electrical Engineering
Electronics and Microelectronics
Graph neural networks
Instrumentation
Internet service providers
Machine learning
Network latency
Network management systems
Network topologies
Networks
Neural networks
Optimization
Power
Research Article
Resource allocation
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Zusammenfassung:Fueled by the explosive growth of ultra-low-latency and real-time applications with specific computing and network performance requirements, the computing force network (CFN) has become a hot research subject. The primary CFN challenge is to leverage network resources and computing resources. Although recent advances in deep reinforcement learning (DRL) have brought significant improvement in network optimization, these methods still suffer from topology changes and fail to generalize for those topologies not seen in training. This paper proposes a graph neural network (GNN) based DRL framework to accommodate network traffic and computing resources jointly and efficiently. By taking advantage of the generalization capability in GNN, the proposed method can operate over variable topologies and obtain higher performance than the other DRL methods.
ISSN:2095-9184
2095-9230
DOI:10.1631/FITEE.2300009