Huawei has begun commercial deployments of its FDD Tri-Band Massive MIMO solution, focusing on sub-3 GHz spectrum across Africa and several other global markets. Countries such as Nigeria, Angola, and Côte d'Ivoire are among the first to benefit, with deployments also expected across Asia Pacific, Central Asia, and Latin America.
This new technology is being positioned to solve two key challenges for mobile operators. First, it tackles the persistent increase in 4G traffic, which continues to grow year on year. Second, it enhances the user experience for 5G services without demanding vast new spectrum allocations. Huawei claims the solution delivers significant performance improvements over the conventional 4T4R setup, including handling almost twice as much 4G traffic during peak times, tripling user-perceived speeds, and halving the use of physical resource blocks.
Underpinning these benefits are innovations like Real Wide Bandwidth and Compact Dipole technologies. These allow multiple FDD bands such as 1.8 GHz, 2.1 GHz, and 2.6 GHz to be processed using a shared filter, antenna array, and power amplifier. This not only enables efficient spectrum use but also simplifies site deployments. Huawei reports that 5G network capacity can be boosted up to sevenfold with uplink coverage extended by 8 dB, both of which are especially important as mobile AI services increase the demand for higher uplink bandwidth and wider coverage.
#Huawei's tri-band FDD Massive MIMO solution is the first of its kind, packed with cutting-edge technologies like GigaBand Beamforming and "0 Bit 0 Watt", which empowers diversified 5.5G experience while minimizing power consumption. 🚀 #MWC24 #5GAdvanced pic.twitter.com/3vD3p8qXmc
— Huawei Wireless (@HuaweiWireless) February 20, 2024
The market conditions in Africa illustrate why this approach is timely. Rapid urbanisation and a large population base have created surging demand for mobile data, leading to congestion and degraded user experience. Many sites already host conventional Massive MIMO technology, but with traffic increasing by 50 percent annually, a more efficient capacity solution is urgently needed.
The broader role of sub-3 GHz FDD spectrum in 5G development is also coming into sharper focus. While early 5G investment emphasised the upper mid-band due to its wide contiguous spectrum, the sub-3 GHz FDD bands now represent a crucial part of the coverage and capacity equation. These bands collectively offer around 100 MHz of paired spectrum and are essential for extending 5G services beyond dense urban centres into suburban and rural areas. Their propagation characteristics provide better in-building penetration and a stronger uplink experience.
Operators have traditionally used these bands to complement mid-band deployments, but case studies suggest they can form the backbone of high-performance networks when optimised correctly. In the Netherlands, for example, delays in mid-band spectrum availability led operators to rely heavily on FDD spectrum. Despite these constraints, they achieved strong data rate and latency performance by tightly integrating 4G and 5G technologies.
One persistent issue is the fragmentation of spectrum across multiple bands, which can complicate radio access network design. Physical site constraints and antenna complexity remain challenges, particularly as physical cell site growth slows. This has led to a push for site simplification through wideband and multiband radio solutions. Many equipment vendors now offer radios that can support three FDD bands within a single unit, often using a shared power amplifier and filter. This not only reduces size and weight but also lowers power consumption and speeds up deployment.
Although Massive MIMO is generally seen as more effective with TDD, Huawei believes its latest advancements in intelligent beamforming and multi-band serving cell configurations can change that narrative. By treating multiple FDD bands as a single carrier and applying advanced beamforming, spectral efficiency can be dramatically improved. According to Huawei, this combination can deliver a tenfold gain in throughput and a 10 dB improvement in coverage compared to standard 4T4R systems.
With the shift toward 5G Advanced on the horizon, operators must get the most out of their existing spectrum assets. Sub-3 GHz FDD spectrum may not be new, but with the right technology, it can provide the performance needed to meet modern data demands and support the next wave of mobile services.
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