A Guard Zone Based Scalable Mode Selection Scheme in D2D Underlaid Cellular Networks

TL;DR

This paper proposes a scalable guard zone-based mode selection scheme for multi-cell D2D underlaid cellular networks, improving throughput by balancing interference management and spectrum utilization using stochastic geometry analysis.

Contribution

It introduces a distributed, scalable guard zone scheme for D2D mode selection, with an analytical framework to optimize throughput in multi-cell networks.

Findings

Enabling D2D improves per user throughput.

Proper guard zones significantly enhance average throughput.

Analytical model efficiently finds optimal guard zone parameters.

Abstract

Underlaying the cellular networks, Device to Device (D2D) communication brings the possibility to significantly improve the spectral efficiency in cellular networks and offload the traffic relayed by the base station. However, it creates new challenge for interference management as well. In this paper, we consider the multi-cell D2D underlaid cellular network in which many D2D links reuse the uplink resource simultaneously. The infeasibility of interference cancellation/alignment motivates us to force the D2D users near the base stations to work in cellular mode. Based on that, we present a distributed and scalable mode selection scheme based on guard zone to make a good tradeoff between decreasing interference penalty to base stations and improving spectrum utilization. With the help of stochastic geometry, we develop an analytically tractable framework to analyze the interference and then throughput for the two kinds of users in the considered scenario. The results obtained by the framework reveal that enabling D2D communication does improve the per user throughput and that a proper guard zone can further significantly increase the average throughput of both kinds of users. Thanks to the tractability of our model, the optimal guard zone, which is the key parameter in our scheme, can be efficiently obtained by finding the root of the first order derivative of the throughput expression. Through extensive numerical analysis, we show insights of the system and give some guidelines in system design aspect.