Adrian Taylor, Regional Vice President of Sales at A10 Networks, looks at the challenges service providers are facing as more and more devices are connected to the internet.
The number of connected devices is on the rise, growing 15% or more year-over-year and projected to be 28.5 billion devices by 2022 according to a Cisco VNI forecast.
Mobile service providers have been challenged to support such a high growth of connected devices and their corresponding increases in network traffic. Adding networking nodes to scale-out capacity is a relatively easy change. Meanwhile, it’s essential to keep offering innovative value-added services, including parental control, URL filtering, content protection and endpoint device protection from malware and ID theft.
Service providers, however, are now facing new challenges of operational complexity and extra network latency coming from those services. Such challenges will become even more significant when it comes to 5G. It will be critical to minimise latency to ensure there are no interruptions to emerging mission-critical services that are expected to dramatically increase with 5G networks.
In a mobile network, there are two segments between the radio network and the internet: the evolved packet core (EPC) and the Gi/ SGi-LAN. The EPC is a packet-based mobile core running both voice and data on 4G/ LTE networks. The Gi-LAN is the network where service providers typically provide various homegrown and value- added services. Service providers need to steer the traffic and direct it to specific service functions, which may be chained, only when necessary, in order to meet specific policy enforcement and agreements for each subscriber.
The Gi-LAN network is an essential segment that enables enhanced security and value-added service offerings to differentiate and monetise services. Therefore, it’s crucial to have an efficient Gi-LAN architecture to deliver a high-quality service experience.
Challenges in the Gi-LAN segment
In today’s 4G/ LTE world, a typical mobile service provider has an ADC, a DPI, a CGNAT and a firewall device as part of Gi-LAN ser- vice components. They are mainly deployed as independent network functions on dedicated physical devices from a wide range of ven- dors. This makes Gi-LAN complex and inflexible from operational and management perspective. Thus, this type of architecture is reach- ing its limits and does not scale to meet the needs of the rising data traffic in 4G and 4G+ architectures. This will continue to be an issue in 5G infrastructure deployments. Two serious issues are increased latency and significantly higher total cost of ownership.
Latency is becoming a significant concern since lower latency is required by online gaming and video streaming services even today. With the transition to 5G, ultra-reliable low-latency connectivity targets latencies of less than 1ms for use cases, such as real-time interactive AR/ VR, tactile internet, industrial automation, mission/ life-critical service like remote surgery and self-driving cars.
The architecture with individual service functions on different hardware has a major impact on this promise of lower latency. Multiple service functions are usually chained and every hop the data packet traversing between service functions adds additional latency, causing overall service degradation.
Consolidating service functions in Gi-LAN
In order to overcome these issues, there are a few approaches you can take. From an architecture perspective, service-based architecture (SBA) or microservices architecture will address operational concerns since leveraging such architecture leads to higher flexibility and automation and significant cost reduction. However, it less likely addresses the network latency concern because each service function, regardless of VNF or microservice, still contributes in the overall latency as far as they are deployed as individual VM or microservice.
So, what if multiple service functions are consolidated into one instance? For example, CGNAT and Gi firewall are fundamental components in the mobile network, and some subscribers may choose to use additional services such as DPI, URL filtering. Such consolidation is feasible only if the product/solution supports flexible traffic steering and service chaining capabilities along with those service functions. By consolidating Gi-LAN service functions into one instance/appliance, it helps drastically reduce the extra latency and simplify network design and operation.
Therefore, when building an efficient Gi-LAN network, service providers need to consider a solution that can offer multiple network and service functions on a single instance/appliance, flexible service chaining support, a variety of form-factor options, high performance and capacity with scale-out capability, and easy integration and transition to SDN/NFV deployment.
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