Your search keyword '"Follow me edge"' showing total 2 results

1. On Enabling 5G Automotive Systems Using Follow Me Edge-Cloud Concept.

Author

Aissioui, Abdelkader, Ksentini, Adlen, Gueroui, Abdelhak Mourad, and Taleb, Tarik

Subjects

*5G networks, *INTERNET, *PUBLIC safety, *MOBILE health, *SMART power grids, *INFRASTRUCTURE (Economics), *MOBILE computing, *CLOUD computing

Abstract

One of the key targets of the upcoming 5G system is to build a mobile network architecture that supports not only classical mobile broadband applications (i.e., Internet and IMS), but also vertical industry services, such as those of automotive systems, e-health, public safety, and smart grid. Vertical industry is known to have specific needs that cannot be sustained by the current cellular networks. More notably, automotive systems require strict quality of service in terms of ultrashort latency for vehicle-to-infrastructure/network (V2I/N) communications. In this paper, we introduce the Follow Me edge-Cloud (FMeC) concept, leveraging the mobile edge computing (MEC) architecture to sustain requirements of the 5G automotive systems. Assuming that automotive services are deployed on MEC entities, FMeC ensures low-latency access to these services by guaranteeing that vehicles (i.e., as well as user equipment on board vehicles) always connect to nearest automotive service. Besides the FMeC architecture, our contribution in this paper consists in presenting a projection of the FMeC solution on an automated driving use case that integrates automotive and Telco infrastructures, to realize the vision of future 5G automotive systems. We introduce the envisioned software defined networking/OpenFlow-based architecture and our mobility-aware framework based on a set of building blocks that permit achieving the automated driving requirements within 5G network. The evaluation results, obtained conjointly through theoretical analysis and computer simulation, show that our proposed solution outperforms baseline approaches in meeting the automated driving latency requirement and minimizing the incurred global cost. [ABSTRACT FROM AUTHOR]

Published

2018

2. On Enabling 5G Automotive Systems Using Follow Me Edge-Cloud Concept

Author

Abdelhak Mourad Gueroui, Tarik Taleb, Adlen Ksentini, Abdelkader Aissioui, Université de Versailles Saint-Quentin-en-Yvelines, Université de Rennes 1, Department of Communications and Networking, Aalto-yliopisto, and Aalto University

Subjects

OpenFlow, Verticals, Computer Networks and Communications, Computer science, Distributed computing, Service mobility, Mobile computing, Automotive industry, Aerospace Engineering, Cloud computing, 02 engineering and technology, 7. Clean energy, SDN, Follow me cloud, 0202 electrical engineering, electronic engineering, information engineering, Electrical and Electronic Engineering, 020203 distributed computing, Automotive driving, Telecomunicaciones, Mobile edge computing, ta213, business.industry, Mobile broadband, Quality of service, MEC, 020206 networking & telecommunications, Follow me edge, Smart grid, Automotive Engineering, Cellular network, The Internet, business, Software-defined networking, 5G

Abstract

One of the key targets of the upcoming 5G system is to build a mobile network architecture that supports not only classical mobile broadband applications (i.e., Internet and IMS), but also vertical industry services, such as those of automotive systems, e-health, public safety, and smart grid. Vertical industry is known to have specific needs that cannot be sustained by the current cellular networks. More notably, automotive systems require strict quality of service in terms of ultrashort latency for vehicle-toinfrastructure/ network (V2I/N) communications. In this paper, we introduce the Follow Me edge-Cloud (FMeC) concept, leveraging the mobile edge computing (MEC) architecture to sustain requirements of the 5G automotive systems. Assuming that automotive services are deployed on MEC entities, FMeC ensures low-latency access to these services by guaranteeing that vehicles (i.e., as well as user equipment on board vehicles) always connect to nearest automotive service. Besides the FMeC architecture, our contribution in this paper consists in presenting a projection of the FMeC solution on an automated driving use case that integrates automotive and Telco infrastructures, to realize the vision of future 5G automotive systems.We introduce the envisioned software defined networking/OpenFlow-based architecture and our mobility-aware framework based on a set of building blocks that permit achieving the automated driving requirements within 5G network. The evaluation results, obtained conjointly through theoretical analysis and computer simulation, showthat our proposed solution outperforms baseline approaches in meeting the automated driving latency requirement and minimizing the incurred global cost. This work was supported in part by the Academy of Finland Project CSN under Grant 311654 and in part by the European Union’s Horizon 2020 research and innovation program under the 5G!Pagoda project under Grant 723172 and EU H2020 5G-Transformer Project under Grant 761536.

Published

2018