Seil Jeon
ABSTRACT
In this paper, we propose a Software-Defined Networking (SDN)-based mobile networking approach with two kinds of controller models. The proposed approach keeps the legacy mobility control plane integrated with SDN, thus being able to realize flexible and scalable cellular networks based on SDN, while supporting enhanced mobility management on the utilization of legacy mobility control plane. That is, such a partially-separated mobile SDN architecture can increase the flexibility of mobility management while maximizing the utilization of the deployed networks, without stripping all the mobility-related legacy equipment from the network. We describe the applicability of the presented approach with exemplary use cases that can be effectively achieved or flexibly implemented over the proposed models. Enhanced performance and implementation challenges are finally presented and discussed.
References
- Cisco Visual Networking Index: Global Mobile Data Traffic Forecast Update, 2013--2018, White Paper, 2014.Google Scholar
- IETF DMM WG, http://tools.ietf.org/wg/dmm.Google Scholar
- Software-Defined Networking: The New Norm for Networks, White Paper, Apr. 2012.Google Scholar
- 3GPP TR 23.829, Services and System Aspects; Local IP Access and Selected IP Traffic Offoad (LIPA-SIPTO), v10.0.1, Oct. 2011.Google Scholar
- 3GPP TS 23.401, GPRS Enhancements for Evolved Universal Terrestrial Radio Access Network (E-UTRAN) access, v11.4.0, Dec. 2012.Google Scholar
- IEEE Std 802.21-2008, Standards for Local and Metropolitan Area: Media Independent Handover Services, 2008.Google Scholar
- LinuxFoundation.org, "iproute2", http://www.linuxfoundation.org/collaborate/workgroups/networking/iproute2.Google Scholar
- A. Banerjee et al. MOCA: A Lightweight Mobile Cloud Offoading Architecture. 2013. Proc. of ACM MobiArch 2013. Google ScholarDigital Library
- C. Guimaraes, D. Corujo, R. L. Aguiar, F. de Oliveira Silva, and P. Rosa. Empowering Software Defined Wireless Networks through Media Independent Handover Management. 2013. Proc. of IEEE GLOBECOM 2013.Google Scholar
- S. Gundavelli, K. Leung, V. Devarapalli, K. Chowdhury, and B. Patil. Proxy Mobile IPv6, 2008. IETF RFC 5213.Google Scholar
- H. A. Hamad et al. An SDN-based Network Architecture for Extremely Dense Wireless Networks. 2013. Proc. of IEEE SDN4FNS 2013.Google Scholar
- G. Hampel, M. Steiner, and T. Bu. Applying Software-Defined Networking to the Telecom Domain. 2013. Proc. of IEEE INFOCOM Workshop 2013.Google Scholar
- S. Jeon, S. Figueiredo, and R. L. Aguiar. On the Impacts of Distributed and Dynamic Mobility Strategy: A Simulation Study. 2013. Proc. of IFIP Wireless Days 2013.Google Scholar
- N. Katanekwa et al. Enhanced Gateway Selection for Optimal Routing in a Distributed Evolving Packet Core (EPC) Network. May 2013. Proc. of ECTI CON 2013.Google Scholar
- J. Kempf, B. Johansson, S. P. H. Luning, and T. Nilsson. Moving the Mobile Evolved Packet Core to the Cloud. 2012. Proc. of IEEE WiMob 2012. Google ScholarDigital Library
- N. McKeown et al. OpenFlow: Enabling Innovation in Campus Networks. 2008. Proc. of ACM Computer Communication Review, vol. 38, no. 2, pp. 69--74. Google ScholarDigital Library
- S. B. H. Said et al. New Control Plane in 3GPP LTE/EPC Architecture for On-Demand Connectivity Service. 2013. Proc. of IEEE CloudNet 2013.Google Scholar
- H. Soliman, C. Castelluccia, K. ElMalki, and L. Bellier. Hierarchical Mobile IPv6 (HMIPv6) Mobility Management, 2008. IETF RFC 5380.Google Scholar
- S. H. Yeganeh and Y. Ganjali. Kandoo: A Framework for Efficient and Scalable Offoading of Control Applications. 2012. Proc. of ACM HotSDN Workshop 2012. Google ScholarDigital Library
Index Terms
SDN-based mobile networking for cellular operators
Comments