As rural broadband initiatives help bridge the digital divide, communications service providers have a wealth of opportunities to add subscribers, expand territory, and grow their business. However, they will first need to address the challenges posed by IPv4 exhaustion—and its impact on the cost of new subscriber IP addresses.
In November 2019, the final allocation of publicly available IPv4 addresses was made. Since then, new IPv4 addresses have been obtainable only at high open market prices. There is a virtually unlimited stock of IPv6 addresses available. But migration to the new standard is a highly complex prospect. It is also impractical in the short term for many communications service providers. They need a more feasible and affordable way to support new subscribers.
Fortunately, there’s another way forward. Carrier-grade NAT (CGNAT), a standard for network address translation (NAT), makes it possible to extend the life of existing IPv4 addresses to support additional subscribers. In this way, communications service providers can capture new growth opportunities—while simultaneously positioning their business for IPv6 migration when the time is right.
Rural Broadband Initiatives Expand Opportunities for Communications Service Providers
Broadband plays a central role in peoples lives. Yet millions of households in rural and urban communities still lack access to high-speed internet from broadband services from either Fibre to the Premises (FTTP), fixed wireless internet, or mobile ISP. It represents a vast potential market for providers. Now accelerating support for rural broadband initiatives and digital divide programs are turbocharging that opportunity.
Meanwhile, demand for broadband services is surging. As the COVID-19 pandemic shifted broad swathes of modern life online, average broadband network usage in the UK doubled in 2020 compared to 2019.
Rural broadband networks have performed well. It is thanks, in part, to infrastructure investments by rural broadband providers and an increase in FTTP penetration. This robust connectivity paves the way for new opportunities for both communications service providers and underserved communities and customers. It facilitates new services such as rich content experiences, new forms of collaboration, distance learning, telehealth, IoT, precision agriculture, and more.
One of the problems that communications service providers will need to address upfront is IPv4 exhaustion. It is a significant issue but a solvable one.
Overcoming IPv4 Exhaustion
The cost of acquiring more IPv4 addresses to support new growth has escalated rapidly over the last few years. This is because the last remaining IPv4 addresses from Regional Internet Registries (RIRs) have been fully allocated. IPv6 migration is a complex and long-term prospect. Even if communications service providers chose to switch over their own infrastructure, they’d still need to support IPv4 to carry IPv4 content and accommodate IPv4 devices.
To accommodate large waves of new customers connecting to broadband services, many communications service providers will need to find a way to extend the utility of their current IPv4 addresses.
Carrier-grade NAT (CGNAT), also known as large-scale NAT (LSN), offers a solution. In a standard NAT design, network address translation enables a single public IPv4 address to be shared across the devices on a private network. CGNAT adds an additional translation layer to NAT that allows service providers to share their own public IPv4 addresses across the private IPv4 networks of multiple subscribers, multiple devices of a single subscriber, or multiple businesses.
By using architecture models like NAT44 or NAT444, CGNAT can expand IP address pools by 40 – 60x or more. It helps communications service providers support new subscribers. It also drives growth without purchasing new IPv4 numbers on the open market or upgrading or enhancing home modems, routers, or cellular phones.
Building DDoS Protection into Growing Networks
Communications service providers are leveraging address translation technologies. They help service providers grow their footprint and reach new rural broadband initiative and digital divide customers. However, they also need to keep security top-of-mind. Service provider networks are big targets for distributed denial of service (DDoS) attacks.
Traditionally, a DDoS attack on a communications service provider’s infrastructure was somewhat isolated. If an individual subscriber was targeted, the attack was contained to their service. However, with a NAT gateway in place, hackers can target the gateway itself to take down the access of large swaths of subscribers. They can also target an individual subscriber and jump to the corresponding NAT gateway to propagate their attack to other subscribers.
A CGNAT solution can help communications service providers protect subscribers from DDoS attacks. It also helps to ensure that the NAT gateway itself is not compromised. Mitigation techniques include IP anomaly protection to recognise and drop traffic from common attack signatures; Internet Control Message Protocol (ICMP) rate-limiting; CPU overload protection caused from spoofing attacks; connection rate limiting; and automatic IP address blacklisting to mitigate attacks targeting NAT pool addresses.
Bridging the Transition to IPv6
While communications service providers address the immediate challenge of IPv4 exhaustion, they should also be making plans for an eventual transition to IPv6. It is an evolution that is already well underway among online content providers and large mobile network operators as they have migrated their networks to 4G and 5G. The interconnected nature of IPv6 adoption makes it a complex and long-term process.
To achieve full IPv6 adoption globally, each link in the chain, from the end-user to the carrier, to the content provider, must be running IPv6. Realistically, not all three of these links in the chain will switch over at the same time. Subscribers will always want to connect to as many endpoints as possible. This will include at least a few IPv4-only websites. It means, even companies with IPv6 implementation in their networks still need to communicate with legacy IPv4 servers and applications. On the other side of the equation, IPv4 customers need to be able to use services developed with IPv6.
A complete carrier-grade networking (CGN) solution should provide both CGNAT and IPv4-IPv6 migration techniques. By enabling connectivity between IPv4 and IPv6 devices, networks, and internet destinations, these solutions can help communications service providers extend the life of their current IPv4 investments. At the same time, they can evolve and manage the hybrid environment resulting from coexisting IPv4 and IPv6 infrastructure.
As communications service providers seek to offer high-speed broadband while also dealing with IPv4 exhaustion and planning for IPv6 adoption, carrier-grade networking, including CGNAT and IPv4-IPv6 transition, is becoming an essential platform for long-term growth.