Boosting performance for software defined networks from traffic engineering perspective

TL;DR

This paper proposes a traffic engineering system for software defined networks that combines oblivious routing with average delay optimization, significantly improving throughput, resource utilization, and latency over existing models.

Contribution

It introduces RACKE+AD, a novel TE system combining oblivious routing and delay-based traffic splitting, outperforming current state-of-the-art models.

Findings

Outperforms SMORE and SWAN by 4.2% and 9.6%.

Achieves 27% better resource utilization.

Delivers 34% more traffic with 50% less latency.

Abstract

Paths selection algorithms and rate adaptation objective functions are usually studied separately. In contrast, this paper evaluates some traffic engineering (TE) systems for software defined networking obtained by combining path selection techniques with average delay and load balancing, the two most popular TE objective functions. Based on TE simulation results, the best TE system suitable for software defined networks is a system where the paths are calculated using an oblivious routing model and its adaptation rate calculated using an average delay objective function. Thus, we propose the RACKE+AD system combining path sets computed using Racke's oblivious routing and traffic splitting objective function using average delay. This model outperforms current state-of-the-art models, maximizes throughput, achieves better network resource utilization, and minimizes delay. The proposed system outperformed SMORE and SWAN by 4.2% and 9.6% respectively, achieving 27% better utilization and delivering 34% more traffic with 50% less latency compared with both systems on a GEANT network.