Experimental Evaluation of End-to-end Flow Latency Reduction in Softwarized Cellular Networks through Dynamic Multi-Access Edge Computing

Over the last few years the Multi-Access Edge Computing (MEC) paradigm has been gaining attention as a key enabler for low latency applications in cellular networks. In this paper we analyze a solution based on Software-Defined Networking (SDN) for supporting dynamic and transparent relocation of th...

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Main Authors: Fondo-Ferreiro, Pablo, Candal-Ventureira, David, Gil-Castineira, Felipe, Gonzalez-Castano, Francisco Javier, Collins, Diarmuid
Format: Conference Proceeding
Language:English
Subjects:
Cellular networks
IP networks
Logic gates
Low Latency
Multi-Access Edge Computing (MEC)
Network function virtualization
Quality of service
Scalability
Software-Defined Networking (SDN)
Telecommunication traffic
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creator Fondo-Ferreiro, Pablo
Candal-Ventureira, David
Gil-Castineira, Felipe
Gonzalez-Castano, Francisco Javier
Collins, Diarmuid
description Over the last few years the Multi-Access Edge Computing (MEC) paradigm has been gaining attention as a key enabler for low latency applications in cellular networks. In this paper we analyze a solution based on Software-Defined Networking (SDN) for supporting dynamic and transparent relocation of the endpoint of a communication from the core to an edge infrastructure in current cellular networks. We also provide results of real-world experiments utilising a Network Function Virtualization (NFV)-based testbed for evaluating session continuity and latency reduction when the gateway or anchor point used by two end User Equipments (UEs) is relocated to edge resources. Our experimental results show that the communication can be dynamically relocated from the core to the edge while guaranteeing session continuity during the whole process. We demonstrate that the mechanism is able to reduce latency considerably when the core network is congested.
doi_str_mv 10.1109/PIMRC50174.2021.9569590
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subjects Cellular networks
IP networks
Logic gates
Low Latency
Multi-Access Edge Computing (MEC)
Network function virtualization
Quality of service
Scalability
Software-Defined Networking (SDN)
Telecommunication traffic
title Experimental Evaluation of End-to-end Flow Latency Reduction in Softwarized Cellular Networks through Dynamic Multi-Access Edge Computing
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