A Comprehensive Real-World Evaluation of 5G Improvements over 4G in Low- and Mid-Bands

TL;DR

This study evaluates real-world 5G performance improvements over 4G in low- and mid-bands, revealing that bandwidth expansion and deployment density are key factors, while advanced MIMO features are underutilized.

Contribution

It provides a comprehensive city-wide measurement-based analysis of 5G versus 4G, quantifying the impact of various technological enhancements in real-world environments.

Findings

Wider channel bandwidth is the main contributor to 5G throughput gains.

Enhanced throughput also depends on better signal conditions via denser deployment and beamforming.

Real-world channel rank often limits MIMO performance, with advanced features underutilized.

Abstract

As discussions around 6G begin, it is important to carefully quantify the spectral efficiency gains actually realized by deployed 5G networks as compared to 4G through various enhancements such as higher modulation, beamforming, and MIMO. This will inform the design of future cellular systems, especially in the mid-bands, which provide a good balance between bandwidth and propagation. Similar to 4G, 5G also utilizes low-band (<1 GHz) and mid-band spectrum (1 to 6 GHz), and hence comparing the performance of 4G and 5G in these bands will provide insights into how further improvements can be attained. In this work, we address a crucial question: is the performance boost in 5G compared to 4G primarily a result of increased bandwidth, or do the other enhancements play significant roles, and if so, under what circumstances? Hence, we conduct city-wide measurements of 4G and 5G cellular networks deployed in low- and mid-bands in Chicago and Minneapolis, and carefully quantify the contributions of different aspects of 5G advancements to its improved throughput performance. Our analyses show that (i) compared to 4G, the throughput improvement in 5G today is mainly influenced by the wider channel bandwidth, both from single channels and channel aggregation, (ii) in addition to wider channels, improved 5G throughput requires better signal conditions, which can be delivered by denser deployment and/or use of beamforming in mid-bands, (iii) the channel rank in real-world environments rarely supports the full 4 layers of 4x4 MIMO and (iv) advanced features such as MU-MIMO and higher order modulation such as 1024-QAM have yet to be widely deployed. These observations and conclusions lead one to consider designing the next generation of cellular systems to have wider channels, perhaps with improved channel aggregation, dense deployment with more beams.