Typography

By Femi Oshiga, vice president of service providers for the Middle East and Africa, CommScope

As an eventful 2020 draws to a close, the telecommunications industry is looking forward to building a future in which connectivity is truly ubiquitous and accessible for all. To help achieve this goal, operators will continue to accelerate their rollouts of 5G networks across the globe in 2021, while governments clear additional spectrum to accommodate more users and data. Concurrently, disaggregation of the RAN will continue as Open RAN deployments gain serious traction and usher in a new generation of products and innovative technology. Let’s take a closer look at these three trends below.



5G and massive MIMO

Although the COVID-19 pandemic and resulting shutdowns have noticeably impacted the global deployment of 5G networks in certain countries and regions, rollouts will continue apace in 2021 as 5G smartphones like Samsung's Galaxy S20 and Apple’s iPhone 12 hit the market. 5G is commercially available in at least seven countries as of early 2020: Bahrain, Kuwait, Oman, Qatar, UAE, Saudi Arabia and South Africa. To support these new devices, we expect operators to focus on pragmatic implementations of 5G networks by assessing which deployments can benefit from active massive MIMO (multiple input/multiple output) deployments.

Massive MIMO substantially increases spectral efficiency to deliver more network capacity and wider coverage. However, operators will have to determine if the extra costs and real-world power requirements associated with active MIMO deployments are justified, or if a passive antennae configuration will suffice. Indeed, initial higher-end massive MIMO deployments in certain geographic locations have reportedly struggled to keep up with power demands and are routinely shut down for hours at a time to conserve energy.

From our perspective, massive MIMO deployments are optimally suited for dense urban deployments, while suburban deployments can benefit from passive antenna solutions. However, massive MIMO deployments face challenges even in urban environments, where upper floors of tall buildings may not be adequately covered if the most appropriate solution isn’t selected.

Choosing the optimal antenna technology for each deployment will therefore be a priority for MNOs in 2021. For high data traffic, operators will look towards 64T64R whereas for sites with moderate traffic requirements, MNOs will deploy 8T8R solutions that would adequately cover urban low-rise buildings, as well as suburban and rural areas.

Clearing the spectrum

Clearing the spectrum to accommodate more users and data is essential to building a future in which connectivity is truly ubiquitous and accessible for all. However, most of the low and mid-band spectrum across the globe has historically been used by the military, commercial satellite operators, wireless internet service providers (WISPs), and utilities. Efforts to repurpose or share these bands for next-generation services typically require the active involvement of incumbent users and government regulators, as well as extensive discussions about mitigating the impact to existing services.

Despite the above-mentioned challenges, we expect governments in 2021 to continue taking the initiative to clear the spectrum for 5G and beyond. For example, in the UAE, the Telecommunications Regulatory Authority (TRA) has allocated spectrum for 5G wireless services.  In Egypt, the National Telecommunications Regulatory Authority (NTRA) has similar plans.  There is now near universal recognition of this need which was amplified in 2020 due to the huge spike in data usage in both countries as a result of the home schooling and working from home during the COVID pandemic.

In Europe, the European Union (EU) is working to open new bands and bandwidths for 5G across all EU countries. These include the following bands: 700MHz-30MHz, 3.5GHz-400MHz and 26GHz ~3GHz. As well, a number of European operators are already leveraging 1800MHz or 2100MHz for 5G in Dynamic Spectrum Sharing mode. In the Middle East and Africa, multiple operators have been allocated spectrum within the C-Band including in the UAE, Saudi Arabia, Qatar, Oman, and South Africa.


Open RAN

In 2021, Open RAN deployments will gain serious traction and usher in a new generation of products and innovative technology. This is because Open RAN supports truly open and interoperable interfaces within and between the various subcomponents of the RAN: the radio, hardware, or baseband unit and software. This paradigm drives innovation by encouraging the growth of an expanded supply ecosystem – while reducing capital costs and single vendor ‘lock-in’ through open interfaces and commodity hardware platforms.

According to Mobile Experts chief analyst Joe Madden, almost every company in the Radio Access market is “looking into” Open RAN, which he expects will be the “choice solution” for coverage issues. As Madden notes, Open RAN hardware and software can be cheaper while achieving similar coverage as traditional architectures.

Open RAN offers several advantages for mobile operators. Firstly, Open RAN helps lower costs with commercial off-the-shelf (COTS) processing equipment for the baseband unit (BBU) and commoditisation of the RU hardware. In addition, Open RAN supports the disaggregation of software from proprietary hardware, thereby facilitating the creation and rapid deployment of new services and operational solutions. As we note above, Open RAN supports a more robust supply chain ecosystem as new vendors enter the market. We therefore see disaggregation of the RAN continuing in 2021 as Open RAN deployments gain significant traction and usher in a new generation of products and innovation such as the tighter integration of radios and antennas.

Moreover, Open RAN will continue to play a significant role in accelerating the rollout of 5G infrastructure by enabling equipment interoperability. Indeed, DISH has selected Open RAN technology for its 5G rollout across the United States – and has committed to covering 70% of the population by June 2023 with its 5G network. In Japan, Rakuten’s 5G network is based on Open RAN architecture, which allows for mixing and matching of the most appropriate technology for subscribers. Meanwhile, Vodafone has confirmed plans to start Open RAN trials in Europe and Africa, with initial trials expected to focus on mobile calls and data services across 2G, 3G and 4G. Additional Vodafone Open RAN trials involving 5G are expected in the future. It should be noted that Vodafone recently became the first mobile operator to activate a live Open RAN 4G site in the U.K. In the Middle East and Africa, a key opportunity will present itself for experts in network integration and managed services providing support to the mobile network operators as they consider evolving their networks to Open RAN. 

As the final weeks of an eventful 2020 draw to a close, the telecommunications industry is looking forward to 2021 and building a better future in which connectivity is truly ubiquitous and accessible for all. Although the COVID-19 pandemic has impacted the global deployment of 5G networks, rollouts will continue apace in 2021 as 5G smartphones like Apple’s iPhone 12 hit the market. To support these new devices, MNOs will focus on pragmatic implementations of 5G networks by assessing which deployments can benefit from active massive MIMO deployments. Government across the globe will also continue to clear additional spectrum to accommodate more users and data, while Open RAN deployments will gain serious traction, ushering in a new generation of products and accelerating 5G rollouts.

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