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Autori principali: Owusu, Evans Tetteh, Agyekum, Kwame Agyemang-Prempeh, Benneh, Marinah, Ayorna, Pius, Agyemang, Justice Owusu, Colley, George Nii Martey, Gazde, James Dzisi
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2501.12829
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author Owusu, Evans Tetteh
Agyekum, Kwame Agyemang-Prempeh
Benneh, Marinah
Ayorna, Pius
Agyemang, Justice Owusu
Colley, George Nii Martey
Gazde, James Dzisi
author_facet Owusu, Evans Tetteh
Agyekum, Kwame Agyemang-Prempeh
Benneh, Marinah
Ayorna, Pius
Agyemang, Justice Owusu
Colley, George Nii Martey
Gazde, James Dzisi
contents This study proposes a novel approach for dynamic load balancing in Software-Defined Networks (SDNs) using a Transformer-based Deep Q-Network (DQN). Traditional load balancing mechanisms, such as Round Robin (RR) and Weighted Round Robin (WRR), are static and often struggle to adapt to fluctuating traffic conditions, leading to inefficiencies in network performance. In contrast, SDNs offer centralized control and flexibility, providing an ideal platform for implementing machine learning-driven optimization strategies. The core of this research combines a Temporal Fusion Transformer (TFT) for accurate traffic prediction with a DQN model to perform real-time dynamic load balancing. The TFT model predicts future traffic loads, which the DQN uses as input, allowing it to make intelligent routing decisions that optimize throughput, minimize latency, and reduce packet loss. The proposed model was tested against RR and WRR in simulated environments with varying data rates, and the results demonstrate significant improvements in network performance. For the 500MB data rate, the DQN model achieved an average throughput of 0.275 compared to 0.202 and 0.205 for RR and WRR, respectively. Additionally, the DQN recorded lower average latency and packet loss. In the 1000MB simulation, the DQN model outperformed the traditional methods in throughput, latency, and packet loss, reinforcing its effectiveness in managing network loads dynamically. This research presents an important step towards enhancing network performance through the integration of machine learning models within SDNs, potentially paving the way for more adaptive, intelligent network management systems.
format Preprint
id arxiv_https___arxiv_org_abs_2501_12829
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle A transformer-based deep q learning approach for dynamic load balancing in software-defined networks
Owusu, Evans Tetteh
Agyekum, Kwame Agyemang-Prempeh
Benneh, Marinah
Ayorna, Pius
Agyemang, Justice Owusu
Colley, George Nii Martey
Gazde, James Dzisi
Networking and Internet Architecture
Artificial Intelligence
Emerging Technologies
Machine Learning
Multiagent Systems
This study proposes a novel approach for dynamic load balancing in Software-Defined Networks (SDNs) using a Transformer-based Deep Q-Network (DQN). Traditional load balancing mechanisms, such as Round Robin (RR) and Weighted Round Robin (WRR), are static and often struggle to adapt to fluctuating traffic conditions, leading to inefficiencies in network performance. In contrast, SDNs offer centralized control and flexibility, providing an ideal platform for implementing machine learning-driven optimization strategies. The core of this research combines a Temporal Fusion Transformer (TFT) for accurate traffic prediction with a DQN model to perform real-time dynamic load balancing. The TFT model predicts future traffic loads, which the DQN uses as input, allowing it to make intelligent routing decisions that optimize throughput, minimize latency, and reduce packet loss. The proposed model was tested against RR and WRR in simulated environments with varying data rates, and the results demonstrate significant improvements in network performance. For the 500MB data rate, the DQN model achieved an average throughput of 0.275 compared to 0.202 and 0.205 for RR and WRR, respectively. Additionally, the DQN recorded lower average latency and packet loss. In the 1000MB simulation, the DQN model outperformed the traditional methods in throughput, latency, and packet loss, reinforcing its effectiveness in managing network loads dynamically. This research presents an important step towards enhancing network performance through the integration of machine learning models within SDNs, potentially paving the way for more adaptive, intelligent network management systems.
title A transformer-based deep q learning approach for dynamic load balancing in software-defined networks
topic Networking and Internet Architecture
Artificial Intelligence
Emerging Technologies
Machine Learning
Multiagent Systems
url https://arxiv.org/abs/2501.12829