xNet: Modeling Network Performance With Graph Neural Networks

Today's network is notorious for its complexity and uncertainty. Network operators often rely on network models for efficient network planning, operation, and optimization. The network model is responsible for understanding the complex relationships between network performance metrics (e.g., de...

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Bibliographic Details
Published inIEEE/ACM transactions on networking Vol. 32; no. 2; pp. 1 - 15
Main Authors Huang, Sijiang, Wei, Yunze, Peng, Lingfeng, Wang, Mowei, Hui, Linbo, Liu, Peng, Du, Zongpeng, Liu, Zhenhua, Cui, Yong
Format Journal Article
LanguageEnglish
Published New York IEEE 01.04.2024
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Business metrics
Complexity
Configurations
Delays
Graph neural networks
Graph representations
Graphical representations
Measurement
Modelling
Network modeling
network performance inference
Neural networks
Optimization
Performance measurement
Planning
Predictive models
Quality of service
Simulators
Topology
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Summary:Today's network is notorious for its complexity and uncertainty. Network operators often rely on network models for efficient network planning, operation, and optimization. The network model is responsible for understanding the complex relationships between network performance metrics (e.g., delay and jitter) and network characteristics (e.g., traffic and configuration). However, we still lack a systematic approach to developing accurate and lightweight network models that are aware of the impact of network configurations (i.e., expressiveness) and provide fine-grained flow-level temporal predictions (i.e., granularity). In this paper, we propose xNet, a data-driven network modeling framework based on graph neural networks (GNN). It is worth noting that xNet is not a dedicated network model designed for a specific network scenario with constraint considerations. On the contrary, xNet provides a general approach to modeling the network characteristics of concern with relation graph representations and configurable GNN blocks. xNet learns the state transition functions between time steps and rolls them out to obtain the full fine-grained prediction trajectory. We implement and instantiate xNet with three use cases. The experimental results show that xNet can accurately predict different performance metrics (i.e. temporal and steady-state QoS) in different scenarios, with performance comparable to state-of-the-art domain-specific models. Compared with traditional packet-level simulators, xNet achieves a speed improvement of more than two orders of magnitude, demonstrating its promising application in real-time optimization of network configurations.
ISSN:1063-6692
1558-2566
DOI:10.1109/TNET.2023.3329357