3 minute read
MEC Transforms the Mobile Ecosystem for Service Providers
from The Integrator
FEATURE
A10 NETWORK
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MEC TRANSFORMS THE MOBILE ECOSYSTEM FOR SERVICE PROVIDERS
Written By: Amr Alashaal, Regional Vice President - Middle East at A10 Networks
Multi-access edge computing (MEC) is transforming the mobile ecosystem. By moving mobile network traffic processing functions from a centralized location to multiple distribution points at the network edge. An MEC architecture allows much lower latency by greatly expanding the types of applications and services that can be delivered. With 5G, MEC extends digital reach while creating new revenue opportunities for both enterprises and service providers— and it helps businesses stay competitive in the new “digital-first” economy. For mobile operators, MEC offers a way to address key priorities in the deployment of 5G networks and the transformation of existing 4G/3G networks, including meeting the heightened expectations of subscribers for a seamless experience with new devices and new applications. Also providing added value to enterprises by providing new applications and services and participating in a new ecosystem and competing or partnering with large cloud providers such as AWS and Microsoft Azure for the same enterprise revenue.
But multi-access edge computing requires pulling apart and redistributing critical functions to operate in a centralized core network. This poses practical deployment challenges around space and power constraints, security, and operational complexity.
CHALLENGE #1 - SPACE & POWER CONSTRAINTS
In the 5G era, the number of sites, including MEC locations, is expected to be up to 100x that of the 4G era. With site maintenance
Amr Alashaal
Regional Vice President - ME, A10 Networks
costs amounting to 2 to 5 percent of total mobile operator revenue, conservation of space and energy is clearly a top priority for 5G profitability.
A key opportunity to minimize space and power requirements while improving performance and reducing latency is optimizing and consolidating functions that in 4G networks exist in the Gi-LAN. Gi-LAN functions that could be moved to the edge include firewalls such as GiFW, GTP/roaming firewall, Diameter firewall, SCTP firewall, and DNS application firewall; DDoS mitigation and detection functions; and other functions such as CGNAT, DPI, traffic steering, and load balancing.
However, in 4G networks, most operators have 10 – 12 different devices in the Gi-LAN, often from different vendors. If an operator has 1,000 MEC nodes, this would mean deploying 10,000 or more Gi-LAN devices across all the nodes, an unmanageable scenario even if each node had adequate space. As operators move to 5G and MEC, they are planning to virtualize as much as possible.
CHALLENGE #2 - SECURITY – DDOS LANDSCAPE
With potentially thousands of additional nodes, MEC significantly increases the attack surface operators must defend. With one central data center or EPC, operators could simply overprovision capacity or DDoS protection to safely absorb a DDoS attack. Overprovisioning may not be possible in space- and power-constrained MEC nodes, and it certainly won’t be cost-effective across a large number of nodes. Each node needs its own protection against DDoS attacks and other threats.
With MEC, operators will have dozens, hundreds, or even thousands of node sites to configure, deploy, turn up, secure, monitor, and maintain. This presents numerous challenges. To begin with, one of the objectives in 5G is to allow operators to more closely align network investment with revenue opportunity and provide capacity on demand. With MEC, though, operators must size and scale not just a single central data center or EPC, but a large number of nodes, each with its own requirements to fit the unique traffic characteristics of the service cluster it serves.
