Heterogeneous Drone Small Cells: Optimal 3D Placement for Downlink Power Efficiency and Rate Satisfaction

TL;DR

This paper presents an optimization framework for deploying heterogeneous drone-based small cells, focusing on 3D placement, power efficiency, and interference mitigation to enhance downlink rate satisfaction.

Contribution

It introduces a novel joint optimization approach for drone placement, power minimization, and interference-aware beamforming in heterogeneous drone small cell networks.

Findings

Optimized drone placement reduces power consumption.

Interference mitigation improves downlink rate satisfaction.

Simulation confirms effectiveness of the proposed methods.

Abstract

In this paper, we consider a heterogeneous repository of drone-enabled aerial base stations with varying transmit powers that provide downlink wireless coverage for ground users. One particular challenge is optimal selection and deployment of a subset of available drone base stations (DBSs) to satisfy the downlink data rate requirements while minimizing the overall power consumption. In order to address this challenge, we formulate an optimization problem to select the best subset of available DBSs so as to guarantee wireless coverage with some acceptable transmission rate in the downlink path. In addition to the selection of DBSs, we determine their 3D position so as to minimize their overall power consumption. Moreover, assuming that the DBSs operate in the same frequency band, we develop a novel and computationally efficient beamforming method to alleviate the inter-cell interference impact on the downlink. We propose a Kalai-Smorodinsky bargaining solution to determine the optimal beamforming strategy in the downlink path to compensate for the impairment caused by the interference. Simulation results demonstrate the effectiveness of the proposed solution and provide valuable insights into the performance of the heterogeneous drone-based small cell networks.