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8 results on '"Abrol, Akshita"'

1. FaiRTT: An Empirical Approach for Enhanced RTT Fairness and Bottleneck Throughput in BBR

Author

Abrol, Akshita, Mohan, Purnima Murali, and Truong-Huu, Tram

Subjects
Computer Science - Networking and Internet Architecture
Abstract

In next-generation networks, achieving Round-trip Time (RTT) fairness is essential for ensuring fair bandwidth distribution among diverse flow types, enhancing overall network utilization. The TCP congestion control algorithm -- BBR, was proposed by Google to dynamically adjust sending rates in response to changing network conditions. While BBRv2 was implemented to overcome the unfairness limitation of BBRv1, it still faces intra-protocol fairness challenges in balancing the demands of high-bandwidth, long-RTT elephant flows and more frequent short-RTT mice flows. These issues lead to throughput imbalances and queue buildup, resulting in elephant flow dominance and mice flow starvation. In this paper, we first investigate the limitations of Google's BBR algorithm, specifically in the context of intra-protocol RTT fairness in beyond 5G (B5G) networks. While existing works address this limitation by adjusting the pacing rate, it eventually leads to low throughput. We hence develop the FaiRTT algorithm to resolve the problem by dynamically estimating the Bandwidth Delay Product (BDP) sending rate based on RTT measurements, focusing on equitable bandwidth allocation. By modeling the Inf light dependency on the BDP, bottleneck bandwidth, and packet departure time after every ACK, we can resolve the intra-protocol fairness while not compromising the throughput on the bottleneck link. Through extensive simulations on NS-3 and comprehensive performance evaluations, FaiRTT is shown to significantly improve the fairness index and network throughput, significantly outperforming BBRv2, for diverse flow types. FaiRTT achieves an average throughput ratio of 1.08 between elephant and mice flows, an average fairness index of 0.98, and an average utilization of the bottleneck link of 98.78%., Comment: Accepted for IEEE ICC 2024 Workshop - DDINS

Published
2024

2. A Deep Reinforcement Learning Approach for Adaptive Traffic Routing in Next-gen Networks

Author

Abrol, Akshita, Mohan, Purnima Murali, and Truong-Huu, Tram

Subjects
Computer Science - Networking and Internet Architecture, Computer Science - Artificial Intelligence
Abstract

Next-gen networks require significant evolution of management to enable automation and adaptively adjust network configuration based on traffic dynamics. The advent of software-defined networking (SDN) and programmable switches enables flexibility and programmability. However, traditional techniques that decide traffic policies are usually based on hand-crafted programming optimization and heuristic algorithms. These techniques make non-realistic assumptions, e.g., considering static network load and topology, to obtain tractable solutions, which are inadequate for next-gen networks. In this paper, we design and develop a deep reinforcement learning (DRL) approach for adaptive traffic routing. We design a deep graph convolutional neural network (DGCNN) integrated into the DRL framework to learn the traffic behavior from not only the network topology but also link and node attributes. We adopt the Deep Q-Learning technique to train the DGCNN model in the DRL framework without the need for a labeled training dataset, enabling the framework to quickly adapt to traffic dynamics. The model leverages q-value estimates to select the routing path for every traffic flow request, balancing exploration and exploitation. We perform extensive experiments with various traffic patterns and compare the performance of the proposed approach with the Open Shortest Path First (OSPF) protocol. The experimental results show the effectiveness and adaptiveness of the proposed framework by increasing the network throughput by up to 7.8% and reducing the traffic delay by up to 16.1% compared to OSPF., Comment: Accepted for publication in the Proceedings of the IEEE International Conference on Communications (IEEE ICC 2024)

Published
2024

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