Joint Frequency Reuse and Cache Optimization in Backhaul-Limited Small-Cell Wireless Networks

TL;DR

This paper proposes a joint frequency reuse and cache optimization scheme for small-cell wireless networks, improving cache hit probability and interference management to enhance overall system performance.

Contribution

It introduces a novel joint design of frequency reuse and caching, with a closed-form analysis and an optimization algorithm for better network performance.

Findings

Achieves higher successful transmission probability than existing schemes.

Effectively balances cache hit probability and interference coordination.

Provides a low-complexity algorithm for parameter optimization.

Abstract

Caching at base stations (BSs) is a promising approach for supporting the tremendous traffic growth of content delivery over future small-cell wireless networks with limited backhaul. This paper considers exploiting spatial caching diversity (i.e., caching different subsets of popular content files at neighboring BSs) that can greatly improve the cache hit probability, thereby leading to a better overall system performance. A key issue in exploiting spatial caching diversity is that the cached content may not be located at the nearest BS, which means that to access such content, a user needs to overcome strong interference from the nearby BSs; this significantly limits the gain of spatial caching diversity. In this paper, we consider a joint design of frequency reuse and caching, such that the benefit of an improved cache hit probability induced by spatial caching diversity and the benefit of interference coordination induced by frequency reuse can be achieved simultaneously. We obtain a closed-form characterization of the approximate successful transmission probability for the proposed scheme and analyze the impact of key operating parameters on the performance. We design a low-complexity algorithm to optimize the frequency reuse factor and the cache storage allocation. Simulations show that the proposed scheme achieves a higher successful transmission probability than existing caching schemes.