HetNetwork Coding: Scaling Throughput in Heterogeneous Networks using Multiple Radio Interfaces

TL;DR

HetNetwork Coding leverages multiple radio interfaces and network coding in heterogeneous networks to significantly increase wireless data throughput, especially under heavy load or poor channel conditions, with gains scaling linearly with interfaces.

Contribution

This paper introduces HetNetwork Coding, a novel approach combining multi-interface radios and network coding to enhance throughput in heterogeneous wireless networks.

Findings

Throughput increases with more radio interfaces.

Greater gains under heavy load or poor channel conditions.

Throughput gains scale linearly with number of interfaces.

Abstract

The explosive demand for data has called for solution approaches that range from spectrally agile cognitive radios with novel spectrum sharing, to use of higher frequency spectrum as well as smaller and denser cell deployments with diverse access technologies, referred to as heterogeneous networks (HetNets). Simultaneously, advances in electronics and storage, has led to the advent of wireless devices equipped with multiple radio interfaces (e.g. WiFi, WiMAX, LTE, etc.) and the ability to store and efficiently process large amounts of data. Motivated by the convergence of HetNets and multi-platform radios, we propose HetNetwork Coding as a means to utilize the available radio interfaces in parallel along with network coding to increase wireless data throughput. Specifically we explore the use of random linear network coding at the network layer where packets can travel through multiple interfaces and be received via multihoming. Using both simulations and experimentation with real hardware on WiFi and WiMAX platforms, we study the scaling of throughput enabled by such HetNetwork coding. We find from our simulations and experiments that the use of this method increases the throughput, with greater gains achieved for cases when the system is heavily loaded or the channel quality is poor. Our results also reveal that the throughput gains achieved scale linearly with the number of radio interfaces at the nodes.