Optimal Load Balancing in Millimeter Wave Cellular Heterogeneous Networks

TL;DR

This paper introduces a new approach to optimize load balancing in mmWave heterogeneous cellular networks by analyzing network characteristics and deriving an optimal bias factor to improve rate coverage probability.

Contribution

It presents a novel analytical framework incorporating mmWave-specific features and derives the optimal bias factor for load balancing in HetNets.

Findings

Optimal bias factor significantly improves rate coverage.

Analytical expressions match numerical simulations.

Network parameters influence optimal bias and coverage.

Abstract

In this paper, we propose a novel and effective approach to optimizing the load balancing in a millimeter wave (mmWave) cellular heterogeneous network (HetNet) with a macro-tier and a micro-tier. The unique characteristics of mmWave transmission are incorporated into the network by adopting the Poisson point process (PPP) for base station (BS) location, the line-of-sight (LoS) ball model for mmWave links, the sectored antenna model for key antenna array characteristics, and Nakagami-$m$ fading for wireless channels. To reduce the load of macro-tier BSs, we consider a bias factor $A_{s}$ in the network for offloading user equipments (UEs) to micro-tier BSs. For this network, we first analyze the loads of macro- and micro-tier BSs. Then we derive a new expression for the rate coverage probability of the network, based on which the optimal $A_{s}$ maximizing the rate coverage probability is found. Through numerical results, we demonstrate the correctness of our analysis and the validity of the optimal $A_{s}$. Importantly, the optimal $A_{s}$ can bring a profound improvement in the rate coverage probability relative to a fixed $A_{s}$. Furthermore, we evaluate the impact of various network parameters, e.g., the densities and the beamwidths of BSs, on the rate coverage probability and the optimal $A_{s}$, offering valuable guidelines into practical mmWave HetNet design.