Litcius/Paper detail

ALBRL: Automatic Load‐Balancing Architecture Based on Reinforcement Learning in Software‐Defined Networking

Junyan Chen, Yong Wang, Jiangtao Ou, Chengyuan Fan, Xiaoye Lu, Cenhuishan Liao, Xuefeng Huang, Hongmei Zhang

2022Wireless Communications and Mobile Computing32 citationsDOIOpen Access PDF

Abstract

Due to the rapid development of network communication technology and the significant increase in network terminal equipment, the application of new network architecture software‐defined networking (SDN) combined with reinforcement learning in network traffic scheduling has become an important focus of research. Because of network traffic transmission variability and complexity, the traditional reinforcement‐learning algorithms in SDN face problems such as slow convergence rates and unbalanced loads. The problems seriously affect network performance, resulting in network link congestion and the low efficiency of inter‐stream bandwidth allocation. This paper proposes an automatic load‐balancing architecture based on reinforcement learning (ALBRL) in SDN. In this architecture, we design a load‐balancing optimization model in high‐load traffic scenarios and adapt the improved Deep Deterministic Policy Gradient (DDPG) algorithm to find a near‐optimal path between network hosts. The proposed ALBRL uses the sampling method of updating the experience pool with the SumTree structure to improve the random extraction strategy of the empirical‐playback mechanism in DDPG. It extracts a more meaningful experience for network updating with greater probability, which can effectively improve the convergence rate. The experiment results show that the proposed ALBRL has a faster training speed than existing reinforcement‐learning algorithms and significantly improves network throughput.

Topics & Concepts

Computer scienceReinforcement learningSoftware-defined networkingLoad balancing (electrical power)Network architectureScheduling (production processes)Distributed computingNetwork performanceComputer networkArtificial intelligenceMathematical optimizationGeometryMathematicsGridSoftware-Defined Networks and 5GIoT and Edge/Fog ComputingAdvanced Computing and Algorithms