Business & Technology
As the availability of 5G begins what is likely to be known as the 5G era, a few daunting questions need to be addressed to ensure its ability to meet the very high expectations that businesses, industries, consumers, and operators have set for it. Its ability to enable change and foster innovation relies heavily on a number of factors, and two of these, often overlooked, are central to it achieving its full potential for transformation:
With 5G, we’re talking about unheard volumes of everything: A 10-fold increase in mobile broadband (eMBB), the support for a super high density of connected devices – up to 1 million devices per square kilometer (mMTC), and the ability to deliver ultra-reliability with ultra-low latency (URLLC). These new benchmarks, and more just like them, are redefining the term “scalability” in mobile networks.
In these 5G mobile networks, simple scalability isn’t enough. 5G provides and requires hyperscalablilty. This goes far beyond simply providing faster 4G services. 5G has the potential to provide the foundation for global innovation across a wide variety of sectors in our society. But achieving that depends on Mobile Network Operators (MNOs) and technology vendors being able to intertwine highly complex technologies and architectures.
If done right, the end result will be a set of scalable and consumable services and use cases that not only meet, but exceed their customers’ needs for digital evolution. Of course, this will not be easy to achieve given factors that are both qualitative (the introduction of technologies that were not present in previous generations of mobile solutions) and quantitative (the number of new technologies, architectures, and third-parties that may be required to deliver a service and/or use case).
Given that enhanced Mobile Broadband (eMBB), massive Machine Type Communications (mMTC), and Ultra Reliable Low Latency Communications (URLLC) serve as the building blocks of 5G use cases, the need for a mix of intertwined technologies and architectures to provide hyperscalability is imperative. From the staggering numbers of connected devices (machines, cars, humans, infrastructures, etc.), to the massive amounts of data being produced, communicated, stored, and analyzed, to the diversity and quantity of the distributed compute, storage, and network resources required to support all of this – the ability to provide and support hyperscalability is key for the success of 5G.
Although 5G is, by default, more secure than any past mobile generation, security still has a much larger role to play in 5G environments than it ever did in anything that came before it. A critical aspect of this security is the safeguarding of the mobile infrastructure itself from cyberattacks, misuse, and related consequences. Although the securing of a mobile infrastructure’s signaling and user plane carries over from 4G implementations, the criticality of 5G-based services to enterprises, industries, and infrastructures now makes it an especially attractive target for threat actors.
A second aspect, this one specific to 5G, is the safeguarding of the services and use cases powered by the technology. Their continued adoption, broad availability, and overall success will depend heavily on the end-to-end security of each use case’s complex ecosystem of technologies and partners.
For both of these security scenarios, what is clear is that security solutions will need to be able to provide inspection, prevention, and detection at speeds that no security solution has ever been able to deliver before. But without the ability to protect hyperscale environments at the speeds required, security will become a bottleneck that will either gate the revolution that 5G is poised to provide, or organizations will have to forego critical security in order to meet business objectives. Neither of these is an acceptable option.
Considering these two 5G requirements – hyperscalability and security – it quickly becomes apparent that a hyperscale-capable security infrastructure is an absolute requirement: one that not only spans the entire 5G infrastructure, but that can also be intertwined throughout the entire mix of technologies, ecosystems, and use cases.
Which is why the recent announcement of Fortinet’s new Network Processor, the NP7, is so relevant and important for 5G security.
Before explaining why, I can imagine some readers raising their fists to the sky and crying out, “An ASIC in 5G? A piece of hardware in what is supposed to be a virtualized/containerized environment? Blasphemy! Security should be a Virtual Network Function (VNF)!”
And yes, the cloud technologies used throughout the 5G infrastructure (New RAN [NR], 5G Core [5GC], Telco cloud, and Multi-Tenant Edge Computing [MEC]) serve as the fundamental building blocks that enable some of the unique capabilities 5G brings to bear. And to address this challenge, Fortinet has developed security VNFs that integrate into each of these environments to provide agile and scalable security that protects the different infrastructure components in the control and user planes, as well as secure various use cases and their ecosystems as may be required.
However, there are well-known areas where the constant availability of hyperscale security services are required throughout the 5G infrastructure. In these cases, VNFs might not be efficient – and therefore inadequate. Physical Network Function (PNF) security is required, at least for the short- to mid-term, due to considerations such as cost/performance, energy efficiency, physical footprint, and ease of implementation. These may include, but are not limited to, Security Gateways (SecGW) for backhaul connectivity (N3), massive Carrier Grade NAT (CGNAT), 5G Core to PDN security, and Roaming security.
So for the foreseeable future, especially as 5G scales and develops, hybrid security will need to be implemented with a mix of security VNFs (VMs and containers) and PNFs. And the NP7-powered, carrier-grade FortiGate PNFs from Fortinet will play a critical role in providing the hyperscale security performance, ultra-low latency, and efficiency that 5G demands, including:
All of this goes to show both the power and benefits of the Fortinet NP7-powered FortiGate PNF for 5G. Imagine providing the same levels of performance with VNFs (where agility and frequent auto-scaling is not required) and you will understand why the new NP7 from Fortinet is key to providing the hyperscale security infrastructure needed for 5G.
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Click here for more information about the new FortiGate 1800F and here for more information about the next-generation Fortinet NP7 processor. The combination offers unprecedented performance and FortiGate’s wide range of market-leading security solutions and service.