Toward Software-Defined Cellular Networks

Li, Li Erran; Mao, Z. Morley; Rexford, Jennifer

doi:10.1109/ewsdn.2012.28

Cited by 321 publications

(207 citation statements)

References 9 publications

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“…The major issue is to create appropriate mapping of the existing network functionalities to the decoupled control and forwarding planes. While a lot of the work is done for wired or optical networks, some proposals are also presented for cellular SDN architecture [3] [6]. For the radio access part of the mobile communication system, two fundamental questions are as follows, i.…”

Section: B Software Defined Radio Access Networkmentioning

confidence: 99%

“…In SDN, control plane relates to all control logic required to manage the network, connections, and forwarding the data packets. From SDN's perspective, base stations, serving gateway (S-GW), and packet gateway (P-GW) of LTE architecture are also performing some control plane functions along with data forwarding in addition to the designated control plane nodes MME (Mobility Management Entity), HSS (Home Subscriber Server), and PCRF (Policy Control and Charging Rules Function) [6]. Although not within the scope of SDN, but it is worthwhile to discuss an extreme approach of re-designing radio access architecture, i.e., the Cloud RAN [5].…”

Section: B Software Defined Radio Access Networkmentioning

confidence: 99%

“…Where the control plane will be located? The centralized controller in the state-of-the-art proposals of SD-RAN, either resides in the core network [6] or in a centralized data centre [3]. The design in [6] tries to push all the control plane functionality into a centralized controller in the core network and proposes the use of local switch agents for scalability.…”

Section: B Software Defined Radio Access Networkmentioning

confidence: 99%

“…The centralized controller in the state-of-the-art proposals of SD-RAN, either resides in the core network [6] or in a centralized data centre [3]. The design in [6] tries to push all the control plane functionality into a centralized controller in the core network and proposes the use of local switch agents for scalability. The proposition in [3] is focused towards refactoring the control plane into a virtualized big base station controller for a geographical area and local controllers within each base station for latency sensitive decision making.…”

Section: B Software Defined Radio Access Networkmentioning

confidence: 99%

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Future RAN Architecture: SD-RAN Through a General-Purpose Processing Platform

Zaidi

Friderikos

Imran

2015

IEEE Veh. Technol. Mag.

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Abstract-In this article, we identify and study the potential of an integrated deployment solution for energy efficient cellular networks combining the strengths of two very active currently research themes: software defined radio access networks (SD-RAN) and decoupled signaling and data transmissions, or beyond cellular green generation (BCG2) architecture, for enhanced energy efficiency. While SD-RAN envisions a decoupled centralized control plane and data forwarding plane for flexible control, the BCG2 architecture calls for decoupling coverage from capacity and coverage is provided through always-on low-power signaling node for a larger geographical area; capacity is catered by various on-demand data nodes for maximum energy efficiency. In this paper, we identify that a combined approach bringing in both specifications together can, not only achieve greater benefits, but also facilitates the faster realization of both technologies. We propose the idea and design of a signaling controller which acts as a signaling node to provide always-on coverage, consuming low power, and at the same time also hosts the control plane functions for the SD-RAN through a general purpose processing platform. Phantom cell concept is also a similar idea where a normal macro cell provides interference control to densely deployed small cells, although, our initial results show that the integrated architecture has much greater potential of energy savings in comparison to phantom cells.

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Section: B Software Defined Radio Access Networkmentioning

confidence: 99%

Section: B Software Defined Radio Access Networkmentioning

confidence: 99%

Section: B Software Defined Radio Access Networkmentioning

confidence: 99%

Section: B Software Defined Radio Access Networkmentioning

confidence: 99%

See 2 more Smart Citations

Future RAN Architecture: SD-RAN Through a General-Purpose Processing Platform

Zaidi

Friderikos

Imran

2015

IEEE Veh. Technol. Mag.

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“…The centralized controller can thus optimize the network performance with the global view of the network and adapt radio resources to the network dynamics, i.e., the channel quality variations and the mobile traffic fluctuations from mobile users (MUs). However, the problems with the software-defined RAN concept lie in the inherent latency due to the totally centralized control plane and the need of large-capacity fronthaul links to connect the BSs and the controller [4], [5]. It thus becomes necessary to design a more flexible software-defined RAN architecture.…”

Section: Introductionmentioning

confidence: 99%

Adapting Downlink Power in Fronthaul-Constrained Hierarchical Software-Defined RANs

Chen

Han

Chang

et al. 2017

2017 IEEE Wireless Communications and Networking Conference (WCNC)

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Abstract-The proof-of-concept software-defined radio access network (RAN) is not flexible enough due to the inherent delay and the necessity of high-capacity fronthaul links. We are hence motivated to propose a hierarchical software-defined RAN architecture, over which the base stations (BSs) are abstracted into multiple virtual local controllers while these local controllers are administered by a high-level controller. Under such a hierarchical network architecture, we particularly investigate in this paper how to adapt the BS transmit power over a long term according to the network dynamics under the constraints of mobile user queue stability and limited fronthaul capacity. We first formulate an off-line stochastic power adaptation problem. Through developing the Lyapunov method, we transform the problem into an approximate on-line optimization task. However, the challenge arises from the introduced per-cluster fronthaul capacity constraint. To solve the task efficiently and avoid extensive information exchange between the high-level controller and the local controllers, we put forward a novel low-complexity algorithm by designing a non-cooperative power adaptation game among the local controllers. Simulations are provided to evaluate the efficacy of the proposed studies.

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