Abstract
Network function virtualization (NFV) sits firmly on the networking evolutionary path. By migrating network functions from dedicated devices to general purpose computing platforms, NFV can help reduce the cost to deploy and operate large IT infrastructures. In particular, NFV is expected to play a pivotal role in mobile networks where significant cost reductions can be obtained by dynamically deploying and scaling virtual network functions (VNFs) in the core network. However, in order to achieve its full potential, NFV needs to extend its reach also to the radio access segment. Here, mobile virtual network operators shall be allowed to request radio access VNFs with custom resource allocation solutions. Such a requirement raises several challenges in terms of performance isolation and resource provisioning. In this work, we formalize the wireless VNF placement problem in the radio access network as an integer linear programming problem and we propose a VNF placement heuristic, named wireless network embedding (WiNE), to solve the problem. Moreover, we present a proof-of-concept implementation of an NFV management and orchestration framework for enterprise WLANs. The proposed architecture builds on a programmable network fabric where pure forwarding nodes are mixed with radio and packet processing capable nodes.
Highlights
To cite this version: Roberto Riggio, Abbas Bradai, Davit Harutyunyan, Tinku Rasheed, Toufik Ahmed
Network Function Virtualization (NFV) promises to reduce the cost to deploy and operate large networks by migrating network functions from dedicated hardware appliances to software instances running on general purpose virtualized networking and computing infrastructures
A rich body of literature exists in the Virtual Network Functions (VNFs) placement [1], virtual network embedding [2], and component placement domains [3], most of these works focus on the problem of mapping an input virtual network request onto a physical virtualized network substrate
Summary
Network Function Virtualization (NFV) promises to reduce the cost to deploy and operate large networks by migrating network functions from dedicated hardware appliances to software instances running on general purpose virtualized networking and computing infrastructures. A rich body of literature exists in the VNF placement [1], virtual network embedding [2], and component placement domains [3], most of these works focus on the problem of mapping an input virtual network request (often in the form of a VNF forwarding graph) onto a physical virtualized network substrate (often offering computational as well as networking resources) These works implicitly assume that once a VNF is mapped on a node, the network substrate virtualization layer will take care of scheduling the various VNFs ensuring both logical isolation and an efficient use of the substrate resources [4].
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