17.1 Introduction

The next generation of cellular systems (5G) is expected to meet the rapidly growing demands for data through densification of networks using high-capacity small cells [1]. As networks become dense (through small cell deployments):

• the cost of bringing fiber to every small cell becomes prohibitively expensive [2]
• inter-cell interference increases and becomes a limiting factor in achieving higher cell capacities [3]
• handover is more frequent, causing the associated handover signaling overhead to increase [4].

Using wireless technologies to lower the cost of wiring (digging/trenching to lay wire/fiber in the ground) a cell, for instance by deploying point-to-point microwave links, is already a well-accepted approach [5]. However, even to meet the 4G cellular data rate requirements, the number of point-to-point microwave links is already very high [6, 7] and 5G networks are likely to be even more dense. The first identifiable issue therefore is a cost-effective method for connecting 5G base stations (BSs) to the network (BS–to-network communication).

Inter-cell interference management necessarily involves inter-BS communication. Extensive studies in 3GPP working groups has revealed that latency is a particularly sensitive issue for the achievable performance of cell-edge throughput and/or interference mitigation schemes ...