Biblio

Cellular networks play a dominant role in how we communicate. But, the current cellular architecture and protocols are overly complex. The 'control plane' protocol includes setting up explicit tunnels for every session and exchanging a large number of packets among the different entities (mobile device, base station, the packet gateways and mobility management) to ensure state is exchanged in a consistent manner. This limits scalability. As we evolve to having to support an increasing number of users, cell-sites (e.g., 5G) and the consequent mobility, and the incoming wave of IoT devices, a re-thinking of the architecture and control protocols is required. In this work we propose CleanG, a simplified software-based architecture for the Mobile Core Network (MCN) and a simplified control protocol for cellular networks. Network Function Virtualization enables dynamic management of capacity in the cloud to support the MCN of future cellular networks. We develop a simplified protocol that substantially reduces the number of control messages exchanged to support the various events, while retaining the current functionality expected from the network. CleanG, we believe will scale better and have lower latency.

As demand for wireless mobile connectivity continues to explode, cellular network infrastructure capacity requirements continue to grow. While 5G tries to address capacity requirements at the radio layer, the load on the cellular core network infrastructure (called Enhanced Packet Core (EPC)) stresses the network infrastructure. Our work examines the architecture, protocols of current cellular infrastructures and the workload on the EPC. We study the challenges in dimensioning capacity and review the design alternatives to support the significant scale up desired, even for the near future. We breakdown the workload on the network infrastructure into its components-signaling event transactions; database or lookup transactions and packet processing. We quantitatively show the control plane and data plane load on the various components of the EPC and estimate how future 5G cellular network workloads will scale. This analysis helps us to understand the scalability challenges for future 5G EPC network components. Other efforts to scale the 5G cellular network take a system view where the control plane is separated from the data path and is terminated on a centralized SDN controller. The SDN controller configures the data path on a widely distributed switching infrastructure. Our analysis of the workload informs us on the feasibility of various design alternatives and motivates our efforts to develop our clean-slate approach, called CleanG.