Fault-Tolerant Small Cells Locations Planning In 4G/5G Heterogeneous Wireless Networks

Keywords

4G HetNets; Fault tolerance; network architecture and design; self organizing networks (SON); self-healing; small cells

Abstract

Fourth/Fifth Generation heterogeneous wireless networks (4G/5G HetNets) use or will use small cells (SCs) to extend network coverage and increase spectrum efficiency. However, the standard and technical specifications do not specify how to plan the locations of the SCs within the network. Several papers introduced strategies for planning the locations of SCs in the 4G HetNet architecture. However, SCs placement strategies to support the self-healing functionality of the 4G/5G self organizing networks framework has not been studied in the literature. The placement of SCs in 4G HetNets such that an SC failure will not interrupt service, hence making the network fault tolerant, is an important design and planning problem that is addressed in this paper. We present an integer linear program formulation for planning operators of managed SC locations with fault tolerance. We allow one SC to fail and by using self-healing, a fault-tolerance service is provided at designated fail-over levels (defined in terms of users throughput). We consider the problem of SC location planning by using offloading in both out-band and in-band modes, and an interference model is presented to consider the in-band mode and to address the effect of interference on SCs placement planning. A novel approach to provide a linear interference model by using an expanded state space to get rid of nonlinearity is introduced. We present numerical results that show how our model can be used to plan the positions of SCs. We also incorporate the existence of obstacles in the planning, such as large structures or natural formations, that might happen in real life. To the best of our knowledge, this is the first work that addresses the planning of SC locations in 4G/5G HetNets in a fault-tolerant manner.

Publication Date

6-1-2017

Publication Title

IEEE Transactions on Vehicular Technology

Volume

66

Issue

6

Number of Pages

5269-5283

Document Type

Article

Personal Identifier

scopus

DOI Link

https://doi.org/10.1109/TVT.2016.2615325

Socpus ID

85027409944 (Scopus)

Source API URL

https://api.elsevier.com/content/abstract/scopus_id/85027409944

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