5G Technology Drivers
5G will provide three different types of connectivity services, summarized below, each targeted at specific categories of use cases and applications. These require various levels of network performance that will be provided by different technologies and network architectures.
· Enhanced Mobile Broadband (eMBB) – ex. video streaming
· Massive Machine-Type Communications (mMTC) – ex. smart cities
· Ultra-reliable Low-Latency Communications (urLLC) – ex. Industry 4.0 automation
eMBB is the first 5G service type offered by Mobile Network Operators (MNOs), as it’s easier to be initially deployed, and is a top consumer mobile network use case, made possible by connecting 5G New Radios (NRs) to existing 4G Evolved Packet Core (EPC) networks in what’s referred to as 5G Non-Stand-Alone (5G NSA).
As MNOs evolve their existing 4G EPC to a highly virtualized 5G Core, more advanced mMTC and urLLC services can and will be made available. These service types are facilitated by the advent of Edge Cloud, which helps provide the very low-latency required by new and emerging applications.
5G is not a static technology and it will continue to evolve, as the entire ecosystem from 5G Core to 5G User Equipment (UE), and everything in between, evolves. This means ongoing innovation across wireless and wireline network domains will only accelerate in years to come. No one vendor can possibly invest and innovate in all areas of the 5G network ecosystem and still deliver best-in-class network technologies and products. Thus, cross-vendor collaboration via partnerships is required to ensure that the end-to-end 5G network ecosystem maintains pace with the frantic innovation timelines associated by applications and use-cases in both the consumer and enterprise markets.
5G Network Trends Towards Openness
There’s much talk (and debate) in the industry related to opening 5G networks to migrate from traditional closed and proprietary vendor solutions. Reasons to open the network include a broader and more secure vendor supply chain leading to increased competition, best-in-class network designs, and improved costs. I personally think the question is not if, but when, 5G networks will open because the openness movement is an unstoppable industry juggernaut.
Of course, it will take time, effort, and a desire to solve inevitable challenges along the way. Similar challenges of open, standards-based solutions were faced in other parts of the global network, but the benefits of openness are simply too strong for wholesale and mobile network operators to ignore. Open designs have come to other parts of networking, such as open submarine cables, standards-based 400ZR coherent optics, Application Programming Interfaces (APIs), and others. The openness juggernaut will not spare 5G, nor should it.
Contrary to popular belief, open 5G networks are not just about freeing operators to choose 5G NRs from one vendor and 5G Baseband Units (BBUs) from another vendor, although this is a key benefit. It’s also about leveraging open physical and software interfaces (APIs) across the entire end-to-end ecosystem including Distributed Units (DUs), Centralized Units (CUs), and xHaul transport networks interconnecting everything. Also included are storage and compute resources that host virtualized 5G network functions, as well as enterprise and consumer applications.
5G networks will be far more virtualized compared to previous generations, with Centralized/Cloud-RAN (C-RAN) architectures becoming increasingly important, as they offer numerous benefits such as improved spectrum control, smaller footprint at cell sites, easier virtualization of network functions on cloud resources, improved economics, and optimized energy consumption.
The combination of traditional Distributed RAN (D-RAN) and C-RAN requires new xHaul (fronthaul, midhaul, backhaul) capabilities for transport networks that are more open, scalable, and automated. Highly instrumented xHaul networks supporting open APIs allow automation to be analytics-driven, which can be a gamechanger, to facilitate end-to-end Network Slicing 5G to support application-specific service levels for each 5G service type.
Openness for Best-in-Class End-to-End 5G Network Solutions
For 5G to be more than just faster 4G, a change in how networks are designed, deployed, and managed is required. 5G will adopt a broad set of new technologies such as 5G New Radios, core virtualization, analytics-driven automation, machine learning, artificial intelligence, coherent optics, FlexEthernet, stringent time and synchronization techniques, Segment Routing, and others.
Will all these be adopted day one? Of course not, but over time, these technologies will find their way into 5G networks at a pace dependent upon each MNO’s unique build-out strategy and target use-case applications. It will take a broad and diverse ecosystem of vendors to deliver these technologies.
Paving the Way to Openness
When Ciena and Samsung announced their collaboration last year, it was an important step for advancing 5G networks that provide best-in-class wireless and wireline components. Ciena provides our best-in-class Routing & Switching Portfolio, which is the infrastructure foundation of Adaptive IPTM, and our Manage, Control, Plan (MCP) domain controller. Samsung provides their 5G RAN, which includes their leading vRAN solutions, and cloud-native 5G Core. Together this creates a best-in-class, end-to-end 5G network solution that spans both the wireless (Samsung) and wireline (Ciena) domains.
